Bmi-1: At the crossroads of physiological and pathological biology.

Bmi-1 is a member of the Polycomb Repressor Complex1 that mediates gene silencing by regulating chromatin structure and is indispensable for self-renewal of both normal and cancer stem cells. Despite three decades of research that have elucidated the transcriptional regulation, post-translational modifications and functions of Bmi-1 in regulating the DNA damage response, cellular bioenergetics, and pathologies, the entire potential of a protein with such varied function remains to be realized. This review attempts to synthesize the current knowledge on Bmi-1 with an emphasis on its role in both normal physiology and cancer. Additionally, since cancer stem cells are emerging as a new paradigm for therapy resistance, the role of Bmi-1 in this perspective is also highlighted. The wide spectrum of malignancies that implicate Bmi-1 as a signature for stemness and oncogenesis also make it a suitable candidate for therapy. Nonetheless new approaches are vitally needed to further characterize physiological roles of Bmi-1 with the long-term goal of using Bmi-1 as a prognostic marker and a therapeutic target.

Introduction

In the Eμ-myc transgenic mice, Bmi-1 (B cell-specific Moloney murine leukemia virus integration site 1) was discovered as a frequent target of the Moloney virus insertion, resulting in virally accelerated B-lymphoid tumors, hence its name. Since its discovery, Bmi-1 has been implicated in a number of biological functions including development, cell cycle, DNA damage response (DDR), senescence, stem cell, self-renewal and cancer. Recently, Bmi-1 has proven to be of significant clinical interest as it has been noted to be overexpressed in a number of diseases and malignancies. This review will seek to give a basic overview of Bmi-1, its functions, and its potential research and clinical implications.

Bmi-1 protein

The Bmi-1 gene localizes on chromosome 10 (10p11.23) encodes for a 37 kDa protein composed of 326 amino acids.2, 3 Its protein structure is highly evolutionarily conserved, demonstrating considerable homology with the Mel-18 gene—a transcriptional repressor of Bmi-1—in humans and the Posterior Sex Combs (Psc) protein in Drosophila melanogaster.2, 4

The functionality of the Bmi-1 protein is primarily characterized by three regions: a central helix-turn-helix (HTH) domain, a conserved RING finger domain at the N-terminal end, and a carboxyl-terminal PEST-like domain.2, 5, 6 The RING domain of Bmi-1 comprises of a three-stranded β-sheet, two zinc binding loops, and an α-helix. The RING domain is required for Bmi-1 to localize to DNA strand breaks, thus critical for its role in DDR. Both the RING and HTH motifs are necessary for prevention of senescence in cells. Thus, these two regions aid in continuing the replicative life span of cells. The HTH domain is also important in binding Bmi-1 to DNA and providing a scaffold for subsequent protein binding. PEST domains are protein regions rich in proline (P), glutamic acid (E), serine (S), and threonine (T) bounded by basic residues that tend to act as proteolytic signals leading to protein degradation. One study noted that the PEST-like domain of Bmi-1 primarily contained proline and serine residues and that the deletion of this region resulted in an increased half-life of Bmi-1 and promoted the proliferation of cells.

In addition to the three primary functional regions, the Bmi-1 protein also contains two nuclear localization signals (NLS): NLS1 and NLS2. Of these two, only NLS2 appears to be functional in nuclear localization of Bmi-1 (Fig 1).

Figure 1

Bmi-1 Function and Protein Structure. (A) A visual representation of the known roles of Bmi-1. (B) Graphic of the Bmi-1 protein structure. Key protein motifs are indicated along with their relative sizes and locations. (HTH – helix-turn-helix; NLS – nuclear localization signal; PEST – motif rich in proline, glutamic acid, serine, and threonine; RING – really interesting new gene).

PcG functionality

As a polycomb group (PcG) protein, Bmi-1 associates with other PcG partners to function as an epigenetic repressor, remodeling chromatin through histone 2A (H2A) monoubiquitination and subsequent methylation at histones. PcG proteins were initially studied in Drosophila melanogaster and identified as transcriptional repressors of Hox genes—homeotic genes that regulate morphogenesis and tissue differentiation.

Consequently, PcG proteins have been studied in their potential connection to cancer stem cells. Like stem cells in healthy tissues, tumors appear to contain a small subset of cells that have the potential to repopulate and affect transcriptional regulation patterns. Since PcG proteins play a role in transcriptional repression, it is hypothesized that they may be highly involved in stem cell renewal and cancer development.

There are two multimeric PcG protein complexes: Polycomb repressor complex 1 (PRC1) and Polycomb repressor complex 2 (PRC2). As these complexes have been investigated, core functional components have been determined for both families of PcG proteins. In humans, the canonical PRC1 is comprised of Bmi-1, RING1A/B, PCGF, CBX, and HPH, while the core PRC2 is comprised of EZH, SUZ12, and EED. (summarized in Table 1). As a part of PRC1, Bmi-1 interacts with RING1B via its own RING domain and enhances the E3 ubiquitin ligase activity to ubiquitinate histone H2A. PRC2 operates as a histone transmethylase that mono-, di-, and trimethylates the Lys27 residue of histone H3. Traditionally, EED has only been associated with PRC2; however, a recent study suggests that EED plays an important role in both PRC1 and PRC2, and thus may potentially be a key coordinator in transcriptional regulation.

Table 1

Components of the PRC1 and PRC2 complexes.

	Protein motif	Function
PRC1
Bmi-1Mel-18CBX2, 6, 7, 8CBX4HPH1, 2RING1A/BSCMH1, SCML2L3MBTL	RING domain5RING domain28Chromodomain144Chromodomain144Zinc finger and SEP domain145RING domain5Zinc finger, SAM and MBT domains146MBT and SPM domains146	E3 ubiquitin ligase5UndeterminedChromatin association,6, 147Chromatin association and sumolyationE3 ubiquitin ligase5
PRC2
EEDEZH1, 2SUZ12PCL1,2,3JARID2AEBP2RBBP4, 7YY1	WD40 domain17, 148SET domain149Zinc finger149PHD finger, TUDOR147Zinc finger, ARID domain, JmjC and JmjN147Zinc finger,147,149WD40 domain147Zinc finger150	PcG binding and stabilization14Histone transmethylase144Histone transmethylase151Hypothesized147Hypothesized147Increases histone Transmethylase activity149,Histone binding147Recruits PcG proteins to DNA150

Listed are the most common proteins that associate as part of PRC1 and PRC2. Also included are the important functional protein motifs and how each protein contributes—if known—to the complex as a whole.

AEBP – adipocyte enhancer-binding protein; ARID – A–T interaction rich domain; CBX – chromobox; EED – embryonic ectoderm development; EZH – enhancer of zeste homolog; HPH – human polyhometic homolog; JARID – Jumonji/ARID containing; L3MBTL – lethal(3)malignant brain tumor-like protein; MBT – malignant brain tumor; PCL – polycomb-like; PHD – plant homodomain; RBBP – retinoblastoma-binding protein; RING – really interesting new gene; SAM – sterile alpha motif; SEP – serine-glutamine-proline; SET – Su(var)3–9, enhancer-of-zeste; SPM – SCM, Ph, and MBT domain; SCMH – sex comb on midleg homolog; SCML – sex comb on midleg-like domain; SUZ – supressor of zeste; TUDOR – domain originally described in Drosophila Tudor protein; WD40 – 40 residue tryptophan and aspartic acid repeat; YY – Yin–Yang.

Mouse models

Murine and human Bmi-1 display a high degree of similarity at the cDNA (92.4%) and at the protein level (98%), making mice the primary model organism for Bmi-1. A definitive study conducted by van der Lugt et al, demonstrated that Bmi-1 knockout mice are characterized by a survival rate of only ∼50% by the third day after birth. Additionally, knockout mice experienced increased frequency of illness, hematopoietic abnormalities in the liver and bone marrow, lymphoid abnormalities in the thymus and spleen, skeletal defects, ataxic gait, and reduced density in cerebellum and neural layers. Hematopoietic cell counts in the Bmi-1 knockout mice were reduced to roughly 30% of wild-type levels and continued to decrease as the mice aged. The majority of thymocytes in the knockout mice were immature, with total thymocyte levels being decreased to below 1%. In vitro, the fetal hematopoietic cells tend to demonstrate considerable growth defects, whereas in vivo the fetal cells developed relatively normally and only displayed severe defects with age. Despite the hematopoietic abnormalities, the red blood cell count and associated blood parameters did not significantly change in the knockout mice.

A further study using Bmi-1 knockout mice found that reactive oxygen species (ROS) increased in various cell populations, especially thymocytes. In this study, the Bmi-1 knockout thymocytes demonstrated diminished oxidative capacity as well as reduced basal mitochondrial oxygen consumption—both of which contributed to an enhanced DNA damage response (DDR).

An interesting Bmi-1 reporter study found that Bmi-1 is highly expressed in quiescent intestinal stem cells (ISCs). Self-renewal proteins Lgr5 and Bmi-1 were fluorescently tagged within mice ISCs and were studied before and after irradiation. Before irradiation, the Bmi-1 expressing ISCs were characterized as quiescent, while the Lgr5 ISCs were shown to be mitotically active. However, upon irradiation, the Lgr5 ISCs demonstrated susceptibility and died out quickly; in contrast, the Bmi-1 ISCs displayed high resistance to irradiation and proliferated to aid in regeneration. This ISC study suggests that Bmi-1 expression in vivo is highly important within injury response and regeneration of stem cells.

Transcriptional regulation

Transcription factors

Bmi-1 has a number of transcriptional and post-transcriptional regulators. N-Myc, c-Myc, Sp1, Twist1, FOXM1, E2F-1 and SALL4 have been shown to positively regulate Bmi-1 expression, while KLF4, Mel-18 and histone deacetylase inhibitors (HDACi) have been shown to suppress expression at the transcriptional level.21, 22, 23, 24, 25, 26, 27, 28, 29, 30 N-Myc and c-Myc were shown to directly target and upregulate Bmi-1 mRNA in a dose-dependent manner. This mechanism may occur by c-Myc binding to the enhancer box sequence in the Bmi-1 promoter region. Zinc finger transcription factor Sp1 was shown to directly interact with and upregulate Bmi-1, possibly by binding to a G/C rich region. Twist1 has been shown to upregulate Bmi-1 in head and neck squamous cell carcinomas through binding PRC2 components like EZH2. Forkhead box transcriptional factor FOXM1 transcriptionally stimulates genes implicated in cell proliferation, and consequently positively regulates Bmi-1 transcription. E2F-1 directly targets both Bmi-1 and MYCN, upregulating both. E2F-1 was also shown to regulate PRC2 components and Bmi-1, but no other PRC1 components. Zinc finger transcription factor SALL4 positively regulated the Bmi-1 promoter in a dose-dependent manner, possibly through SALL4-induced hypermethylation at Lys4 on histone H3. Zinc finger protein KLF4 was shown to bind to and repress Bmi-1 expression in colon cancer. Mel-18 reduces Bmi-1 expression by repressing Myc, a positive regulator of Bmi-1.27, 28 HDACi have been shown to repress PRC2 components as well as Bmi-1 expression. While the correlations between Bmi-1 transcription and these transcription factors have been characterized, the exact mechanisms and interactions of many of these transcription factors still require further investigation.

Regulation by miRNA

MicroRNAs (miRNAs) are short 21–23 nucleotide RNA sequences that post-transcriptionally regulate gene expression. Bmi-1 expression is repressed by miRNAs in a number of malignancies. We showed that miR-15 and miR-16 directly downregulated expression of Bmi-1 in ovarian cancer. Within gastrointestinal cancer, miR-30e* has been identified to suppress Bmi-1. miR-135a suppresses Bmi-1 expression in pancreatic ductal adenocarcinoma. miR-141 induces senescence in diploid fibroblasts by repressing Bmi-1, EZH2, and consequently, PRC1 and PRC2 activities. In melanomas, miR-203 has been shown to suppress Bmi-1 expression. And finally, miR-320a was shown to directly target Bmi-1 and suppress its expression in nasopharyngeal carcinoma. Together, these reports indicate that depending on the cancer context a variety of miRNAs target the Bmi-1 mRNA, nonetheless suggesting the importance of Bmi-1 in various malignancies.

Post-translational modifications

Post-translational modification (PTM) of Bmi-1 is a relatively under-explored field and is directly associated with the functionality of the protein. Several PTMs of Bmi-1 have been reported, of which sumoylation, phosphorylation, acetylation and ubiquitination are of particular interest. Although the reports related to each such modification are limited and restricted to tissue and/or cancer types, it is interesting to note the diversity in the functional alteration that each such modification induces. The following paragraphs will further discuss how site-specific phosphorylation of Bmi-1 by different kinases, influence its tumorigenicity both positively and negatively.

Acetylation has been shown to influence the nuclear arrangement and function of the Bmi-1. Through time-lapse confocal microscopy, micro-irradiation by UV laser (355 nm), and GFP technology, the dynamics and recruitment of Bmi-1 to UV-damaged chromatin were studied. Bmi-1 was rapidly recruited (half-time t¼15 s), suggesting that Bmi-1 might be required for recognition of UV-damaged sites. Histone hyper-acetylation, stimulation by HDACi/TSA, suppression of transcription by actinomycin D, and ATP-depletion were all shown to prevent increased accumulation of Bmi-1 to γH2AX-positive irradiated chromatin. While there was no direct evidence of acetylated Bmi-1, this demonstrated that the nuclear arrangement of Bmi-1 was influenced by acetylation and occurred as an early event prior to the recruitment of HPβ to the UV-irradiated chromatin.

CBX4, a component of the PRC1, has also been shown to accumulate at sites of DNA damage as a part of the DDR pathway. A novel role for CBX4 as an early DDR protein involved SUMO conjugation at sites of DNA lesions. DNA damage stimulates sumoylation of Bmi-1 by CBX4 at Lys88, which is required for the accumulation of Bmi-1 at DNA damage sites. Moreover, CBX4 recruitment to the sites of laser micro-irradiation-induced DNA damage requires PARP activity but does not require H2AX, RNF8, Bmi-1 nor PI-3-related kinases. The importance of CBX4 in the DDR was confirmed by the depletion of CBX4, which resulted in decreased cellular resistance to ionizing radiation. Both the studies interestingly indicated that a PTM of Bmi-1—either acetylation or sumoylation—is an important prerequisite for recruitment of Bmi-1 to initiate the DDR pathway.

Several groups have simultaneously reported on phosphorylation of Bmi-1. Phosphorylated Bmi-1 at different serine residues modified both the Ink4a/Arf dependent and independent functions. As a PcG protein, Bmi-1 is phosphorylated by 3 pK (MAPKAP kinase 3), which is a convergence point downstream of activated ERK and p38 signaling pathways that have been implicated in differentiation and developmental processes.In vitro and in vivo experiments—as well as yeast two-hybrid interaction and co-immunoprecipitation—established 3 pK as an interacting partner of PRC1 via Bmi-1. Gain of 3 pK activity—either through genetic or pharmacological intervention—resulted in phosphorylation of Bmi-1 and other PcG members, and in their dissociation from chromatin, culminating in de-repression of targets. One such reported Bmi-1 target is the Cdkn2a/Ink4A locus. Cells overexpressing 3 pK showed PcG complex/chromatin dissociation and concomitant de-repression of p14Arf, which was encoded by the Cdkn2a/Ink4A locus. Thus, 3 pK is a candidate regulator of phosphorylation-dependent PcG/chromatin interaction.

Bmi-1 was also reported to be phosphorylated by PI3K/Akt pathway. Both Bmi-1 and Akt were coactivated in a substantial fraction of human high-grade tumors. Akt mediated Bmi-1 phosphorylation, enhanced its oncogenic potential in an Ink4a/Arf-independent manner. This process also modulated the DDR and affected genomic stability. These experiments placed Bmi-1 in a close niche of cellular signaling networks, opening up a world of possibilities as to how external signaling stimuli—in collaboration with chromosomal modifications through the Bmi-1/PRC1 complex—can dictate an oncogenic outcome. These data have direct bearing in providing new mechanistic insights into the modulation of Bmi-1 function by phosphorylation, either by 3 pK or by Akt.

Another independent study showed that phosphorylation of Bmi-1 by Akt could also modulate its function through the Ink/Arf pathway. Phosphorylation of human Bmi-1 at Ser316 by Akt impaired its function by triggering dissociation from the Ink4a/Arf locus, which resulted in decreased ubiquitination of histone H2A and the inability of Bmi-1 to promote cellular proliferation and tumor growth. Moreover, Akt-mediated phosphorylation of Bmi-1 also inhibited its ability to promote self-renewal of hematopoietic stem and progenitor cells. These studies provide a mechanism for the increased abundance of p16Ink4a and p14Arf observed in cancer cells with an activated phosphoinositide 3-kinase (PI3K)/Akt signaling pathway, and identify crosstalk between phosphorylation events and chromatin structure. Together these reports point to the context dependent variability in functional outcome of phosphorylated Bmi-1.

Other important aspects of modulating Bmi-1 function are through the alteration in protein stability via ubiquitination. A recent study by Sahasrabuddhe et al, identified that Bmi-1 contains a functional recognition motif for the F box protein βTrCP, which regulates ubiquitination and proteasome-mediated degradation of various proteins. Overexpression of wild-type βTrCP—but not the ΔF mutant—promoted Bmi-1 ubiquitination and degradation. Also, compared to wild-type Bmi-1, the ΔF mutant protein exhibited increased pro-oncogenic activity. In summary, this finding establishes the importance of ubiquitination of Bmi-1 in regulating the turnover of Bmi-1 and its functional relevance in oncogenesis.

Regarding the existing data on PTMs of Bmi-1, it appears that the field is still at a nascent stage and further evidence needs to be accumulated to fully elucidate the diversified role of Bmi-1 in various physiological processes. However, it is not premature to speculate that PTMs of Bmi-1 are most likely cancer-tissue specific and that the specific site largely dictates the unique physiological role that this protein plays.

Bmi-1 in cellular physiology

Development

As previously noted, the PcG complexes were first identified as trans-acting regulators of homeotic gene function in Drosophila. Two clusters of homeotic genes, the antennapedia complex and the bithorax complex, collectively referred to as the homeotic complex are responsible for the determination of segmental identities in Drosophila. In vertebrates, PcG complexes regulate the self-renewal of various types of embryonic and adult stem cells44, 45 as well skeletal malformations.46, 47 PcG proteins are also evolutionarily conserved chromatin modifiers that can transcriptionally silence their targets through many rounds of cell division during development. Bmi-1 is arguably the PcG protein most strongly associated with neoplastic development.

Bmi-1 plays an important role in morphogenesis during embryonic development and in hematopoiesis throughout pre- and post-natal life. In most tissues, low levels of the Bmi-1 mRNA are detected, whereas higher mRNA levels are found in thymus, heart, brain, and testes. Bmi-1 is also expressed in embryonic stem cells (ESCs) during embryonic development and in the placenta. Bmi-1 has an important role in anterior–posterior axis specification and in maintaining the correct spatial Hox gene expression pattern.49, 50 Loss of function of Bmi-1 has pleiotropic effects. Mice lacking Bmi-1 exhibit a homeotic posterior transformation coupled with strong proliferative defects during lymphocyte development, and also neurological abnormalities. In absence of Bmi-1, primary embryonic fibroblasts are unable to progress into S phase and to undergo premature senescence. Bmi-1 functions in normal development and stem cell maintenance have been attributed to its transcriptional repression of the Ink4a/Arf locus (Fig 2).45, 52, 53 In the central and peripheral nervous system, Bmi-1 deficiency is associated with increased expression of p16Ink4a and p19Arf, and inactivation of p16Ink4a in Bmi-1−/− mice partially rescued the self-renewal defect of Bmi-1−/− neural stem cells (NSCs). The PcG members are dynamically expressed throughout pre-implantation and development.55, 56 Recently Lavialy et al, reported a regulatory pathway that underlies cell fate allocation during early development. This process mechanistically links Bmi-1 to the lineage-specific transcription factors Nanog and Gata6. Bmi1 is repressed by Nanog in ESCs and highly expressed in the extraembryonic endoderm (XEN) and trophectodermal stem cells (TSCs) where Nanog is not present. Bmi-1 physically interacts with Gata6 in extraembryonic primitive endoderm derived XEN cells and controls its protein stability and resultant activity by inhibiting Gata6 ubiquitination and proteasome-mediated degradation. Interestingly, Bmi-1 also interacts with and maintains high Gata3 protein levels in TE-derived TSCs, suggesting a broader function for Bmi-1 in extraembryonic lineage formation and maintenance.

Figure 2

Role of Bmi-1 in Ink4a/Arf Pathway. This figure shows how PRC1 component Bmi-1 helps in the mediation of transcriptional repression at the Ink4a/Arf locus. This mechanism leads to downstream repression of cell cycle and oncogenic pathways.

Cell cycle

The normal cell cycle progression and regulation is tightly controlled by a variety of molecular checkpoints that supervise the various biological functions of the cell that occur within the different phases of the cell cycle. Bmi-1, being a transcriptional repressor and PcG protein, plays an important role in cell cycle regulation. Bmi-1 controls self-renewal and cell cycle by regulating the tumor suppressor proteins p16Ink4a and p14Arf.60, 61 Bmi-1 promotes CDK4 and CDK6 activity by repressing the Ink4a/Arf locus, which encodes the CDK4/6 inhibitor p16Ink4a and p19Arf (a homolog of human p14Arf) that activates p53 (Fig 2). Bmi-1 can also directly regulate p53 stability, further stressing its role in cellular proliferation and tumorigenesis by negatively acting through the pRb-p53 pathway.62, 63 The p16Ink4a protein inhibits binding of Cyclin D to CDK4/6, resulting in the suppression of retinoblastoma (Rb) activity and induction of cell cycle arrest.51, 60 p19Arf induces p53 and causes cell cycle arrest.51, 64 Bmi-1 promotes cell proliferation by suppressing p16Ink4a/Rb and/or p14Arf/MDM2/p53 tumor suppressor pathways. The absence of Bmi-1 is reported to relieve the repression of the Ink4a, resulting in the expression of p16Ink4a and p14Arf. Bmi-1 abolishes cell cycle checkpoints p16/p14 in various cell types. The cell cycle checkpoint that involves the Ink4a/Arf-p53-pRb axis has been described as the principle barrier to the initiation and maintenance of neoplastic transformation.65, 66

In contrast, a few studies have also reported that the proto-oncogene Bmi-1 is required for hepatocellular carcinoma (HCC) cell proliferation; however, the effect of Bmi-1 in promoting HCC cell growth was independent of the Ink4a/Arf status.67, 68, 69 The crosstalk among the proteins active in these pathways and in the epigenetic control of Ink4a/Arf expression has been widely investigated to characterize the role of proto-oncogenes that negatively affect this molecular checkpoint.70, 71 The down-regulation of Bmi-1 also inhibits HCC cell growth independent of Ink4a/Arf status. In mouse tumor cells induced by Bmi-1/RasV12, there is no down-regulation of p16Ink4a or p19Arf expression. A recent report evidenced that PRCs regulate cellular proliferation and transformation independently of the Ink4a/Arf-pRb-p53 pathway. PRCs localize at replication forks, and the loss of their function directly affects the progression and symmetry of DNA replication forks. Ink4a proteins function as antagonists of the Cyclin D–CDK4/6 complex, thereby hindering phosphorylation of Rb family members and consequent entry into S phase. p19Arf, in contrast, is not a CDK inhibitor and instead positively regulates p53. Deletion of both p16Ink4a and p19Arf through the disruption of the entire Ink4a locus has minimal consequences for HSC activity. Their limited expression is likely the result of transcriptional repression by Bmi-1, which is expressed preferentially in HSCs and actively represses the Ink4a locus.18, 74 Bmi-1 deficiency is lethal in adult mice due to hematopoietic failure caused by a progressive depletion of HSCs.18, 74 The escalation in p16Ink4a and p19Arf expression caused by Bmi-1 removal may completely inhibit the infrequent cell cycle entry of adult HSCs, which is crucial for HSC self-renewal and maintenance of blood homeostasis. Recent reports also suggested that Bmi-1 controls mouse glioma development in an Ink4a/Arf independent manner. Bmi-1 knockdown significantly inhibits cell growth in both wildtype and p16Ink4a null Ewing sarcoma and medulloblastoma cell lines. Thus, although inhibition of Ink/Arf tumor suppressor gene expression has been widely considered to be the key mechanism for the oncogenic activity of Bmi-1, more recent data suggest a critical role of Ink/Arf independent mechanisms for Bmi-1 during carcinogenesis.

DNA damage response

Genome integrity is constantly challenged by endogenous (metabolic) and exogenous (environmental) sources. To combat threats posed by DNA damage, cells have evolved mechanisms that are collectively termed as DDR. DDR involves a plethora of proteins whose sequential recruitment and function at DNA damage sites are modulated by numerous highly dynamic and reversible PTMs, including phosphorylation, ubiquitination, acetylation, methylation and sumoylation.

Bmi-1 is known to play a key role not only in preventing DNA damage, but also in DDR. Mitochondrial ROS has been known to be a prominent agent for oxidative DNA damage. Liu et al, has demonstrated that independent of p16Ink4a, Bmi-1 has a role in maintaining mitochondrial function and redox homeostasis. Further, cells lacking Bmi-1 have significant mitochondrial dysfunction accompanied by a sustained increase in ROS that is sufficient to engage the DDR pathway. We also have shown that silencing Bmi-1 in ovarian cancer model leads to increased ROS generation that induces PARP cleavage and apoptosis. Thus, Bmi-1 prevents oxidative DNA damage.

Apart from protecting against oxidative DNA damage, Bmi-1 has been shown to be a key component in DDR, as it is required and sufficient to recruit the DDR machinery to DNA double-strand break (DSB) sites in response to radiation and can prolong NSC survival. Facchino et al, have shown that Bmi-1 is enriched at the chromatin after irradiation, localized and co-purified with ataxia telangiectasia mutated (ATM) protein and γH2AX. Bmi-1 was also shown to preferentially co-purify with non-homologous end joining proteins DNA-PK, PARP-1, hnRNP U, and histone H1 in CD133+ glioblastoma cells.

Following DNA damage, Bmi-1 tethers RING finger protein 2 (RNF2 or RING1B) to DNA, and associates more stably with damaged compared to undamaged chromatin. Computational models based on a recently derived crystal structure of Bmi-1–RING1B–ubiquitin-conjugating enzyme H5c (UbcH5c) suggest that the complex binds to both nucleosomal DNA and histone H4, whereas initial recruitment of RING1B–Bmi-1 to DSBs is dependent on sumoylation of Bmi-1. As previously discussed, the PRC1 complex member CBX4 promotes sumoylation (SUMO-1) of Bmi-1 at Lys88 (K88), while the Bmi-1 K88R mutant failed to be recruited to the repair foci. RING1B–Bmi-1 catalyzes mono-ubiquitination of H2AX/H2A at Lys119 and Lys120 (Lys118 and Lys119 in H2A).7, 80, 81, 82 This modification is essential for the recruitment of ATM to damage site, and consequently, is necessary for efficient formation of γ-H2AX.81, 82 Although Bmi-1 is required for initial recruitment of ATM, ATM is required for sustained localization of Bmi-1 at breaks, which is important for efficient homologous recombination.

Further experimentation will be required to dissect the mechanism by which sumoylation mediates RING1B–Bmi-1 assembly at DSBs, and how H2AX ubiquitination enables binding of ATM. Initial studies suggest that ubiquitination of H2A may weaken interaction with DNA, destabilizing the nucleosome, thus helping in binding of other DDR proteins.

Therefore, by inhibiting ROS induced oxidative DNA damage along with facilitating DDR, Bmi-1 contributes to maintaining genome integrity and resistance to genotoxic therapeutic reagents. Since the efficacy of cancer chemotherapy and radiotherapy relies on generation of DNA damage that is recognized and repaired by intrinsic DNA repair pathways, high expression of Bmi-1 correlates with therapy failure and could be a biomarker for resistance of DNA damaging therapy. Along these lines Sauvageau et al, showed that transformed human cell lines as well as primitive hematopoietic cells exhibited a high frequency of spontaneous chromosome breaks upon Bmi-1 depletion and were hypersensitive to genotoxic agents. Bmi-1 was recruited rapidly to the DNA damage foci where it blocked transcriptional elongation. In addition, Bmi-1 was required for homologous recombination repair and checkpoint recovery.

Senescence and stem cells

Cellular senescence is characterized by an irreversible cell cycle arrest often in response to acute insults in an attempt to prevent damaged or mutated cells from proliferating uncontrollably. Histone deacetylase-associated Sin3B protein is implicated in cell cycle withdrawal, where it is transcriptionally upregulated. Sin3B has been identified as a novel direct target of Bmi-1, where Bmi-1-driven repression of Sin3B as an essential regulator of cellular senescence has been proposed. Bmi-1 has also been reported to prevent senescence and immortalize cells through the activation of telomerase in breast cancer cells and ovarian cancer cells, where elevation of Bmi-1 expression is closely correlated to the increased telomerase activity. Human telomerase reverse transcriptase (hTERT) expression, which leads to induction of telomerase activity is a direct target of c-Myc–induced transcription in mammary epithelial cells (MECs)89, 90 Apparently, Bmi-1, being a transcriptional repressor, acts independently from c-Myc. These data suggest that Bmi-1 regulates telomerase expression in MECs and might play a role in the development of human breast cancer. Deletion analysis of the Bmi-1 protein suggested that the RING finger, as well as a conserved HTH domain, were required for its ability to induce telomerase and immortalize MECs. However, Bmi-1 induction of telomerase is cell type specific; Bmi-1 fails to induce telomerase in fibroblasts. This is consistent with the observation that Bmi-1 overexpression did not immortalize human fibroblasts. It is not known whether Bmi-1 is involved in telomere function in normal breast stem cells. However, in the fetal liver, Bmi-1 was reported to play equally important roles both in the normal as well as progenitor stem cells. Hosen et al, showed that the expression of Bmi-1 is high in primitive HSCs, and is decreased when HSCs are differentiated into a particular lineage. The self-renewal and maintenance of HSCs and NSCs were reported to depend on the levels of Bmi-1.60, 64 These reports suggest a strong correlation between Bmi-1 and the differentiation and renewal of stem cells.

Bmi-1 is reported to play a crucial role during the self-renewal and maintenance of prostate, intestinal, lung epithelial and bronchioalveolar stem cells.93, 94, 95 It would not be out of place to underscore the commonality between stem cells and cancer cells to micromanage the bioenergetic needs for influencing epigenetic/genetic programs. Stem cells are characterized by well classified energetic and biosynthetic demands compared to quiescent differentiated cells. Changing gears between the glycolytic and mitochondrial oxphos pathways triggers differentiation or reprogramming to pluripotency that are furthermore accompanied by consequent changes in cell cycle, biomass, metabolite levels, and redox state. So either a direct or indirect role of Bmi-1 in regulating the cellular bioenergetics may be well conceived as a strategy to answer how Bmi-1 integrates with epigenetic and genetic programs to coordinately regulate stem cell lineage and/or fate.

Stem cells are of two types: ESCs and adult stem cells (ASCs). ESCs are pluripotent stem cells capable of developing into different cells; while ASCs maintain and repair their resident tissues in adult organisms. Thus, self-renewal, differentiation, and prevention of senescence of ASCs are critical for tissue homeostasis. Aging is the progressive decline in physiology and function of adult tissues often attributable to the loss of regenerative capacity of ASCs. ASCs play key roles in overall tissue homeostasis and repair. The function of ASCs declines with age, which may contribute to the physiological decline in tissue homeostasis and the increased risk of neoplasm during aging. Control of gene expression by chromatin remodeling is critical for ASC function.

Bmi-1 plays a crucial role in self-renewal and differentiation of leukemic stem and progenitor cells. In breast cancer cells, gain of Bmi-1 function resulted in increased self-renewal and promoted epithelial–mesenchymal transition (EMT), while contrasting phenotypes were reported with Bmi-1 knockdown through regulation of Nanog expression via the NFκB pathway.

In the nervous system, Bmi-1 is also required for the self-renewal of adult NSCs. Both constitutive deletion and acute knockdown of Bmi-1 result in impaired self-renewal of cultured NSCs isolated from young adult mice. The effect of Bmi-1 knockdown on NSCs is aggravated if NSCs are isolated from adult as opposed to embryonic and postnatal mice. In vivo, Bmi-1 deficiency causes a decrease in the numbers of proliferating, bromodeoxyuridine positive SVZ cells (neural progenitors) without affecting apoptosis.54, 100

In addition to modulating the self-renewal of stem cells, Bmi-1 regulates stem cell differentiation potential in both HSCs and NSCs. Loss of Bmi-1 does not block the differentiation of more committed hematopoietic progenitors,51, 101 but affects the ability of stem cells and early progenitors to retain all cell fate choices. In culture, HSCs from young adult Bmi-1-deficient mice have reduced multi-lineage potential compared with wild-type HSCs when assessed at early passage. The effects of Bmi-1 on HSC differentiation have been linked to its effects on chromatin state. In a mixed population of HSCs and multipotent progenitors (IL7Rα−/KLS), Bmi-1 binds at genomic loci that are marked by both repressive H3K27me3 and active H3–K4me3, a ‘bivalent’ chromatin state associated with genes that are poised to be expressed during differentiation. Constitutive loss of Bmi-1 in the HSC/multipotent progenitor population results in a reduction in H3K27me3 binding, de-repression of B-cell lineage factors and consequent increase in B-lymphopoiesis. Thus, Bmi-1 is a promising candidate for the regulation of HSC differentiation potential during aging. Bmi-1 function in young adult HSC and NSC self-renewal is mediated, in large part, through its transcriptional repression of the p16/p19 aging locus. p16Ink4a inhibits Cyclin-D/CDK4/6 complexes to control cell cycle and senescence, whereas p19Arf contributes to cell cycle control, senescence and apoptosis through the regulation of p53.

Genetic experiments suggest that in HSCs, p16Ink4a is the dominant mediator of the effects of Bmi-1 on stem cell proliferation. Deletion of the entire p16/p19 locus, but not that of p19Arf alone, can mostly rescue the effect of Bmi-1 deficiency on HSC self-renewal in long-term competitive repopulation assays. p19Arf may be a more critical target in adult NSCs, as p19Arf deletion partially rescues self-renewal defects caused by Bmi-1 deficiency, although to a lesser extent than deletion of the entire p16/p19 locus.64, 106 In contrast to chronic Bmi-1 loss, acute RNA interference-mediated knockdown of Bmi-1 in NSC cultures from young adult mice does not lead to an increase in p16Ink4a or p19Arf expression, but instead results in altered expression of another cell cycle inhibitor, p21CIP1, which can rescue the anti-proliferative phenotype of Bmi-1 knockdown. Thus, acute loss of Bmi-1 is likely insufficient for bringing about quick changes to the chromatin state of the p16/p19 locus; however, constitutive deletion of Bmi-1 may result in gradually accumulating and stably maintained activating chromatin marks, such as H3K4me3 or histone acetylation, at the p16/p19 locus.

The expression of Bmi-1 itself does not change significantly in isolated HSC and NSC populations during aging.108, 109 By contrast, the role of Bmi-1 in maintaining self-renewal and multipotency notably declines during aging, arguing for altered activity of Bmi-1 at yet unidentified targets. Indeed, growing evidence proposes additional age-related targets for Bmi-1 in addition to p16Ink4a/p19Arf. Overexpression of Bmi-1 in HSCs isolated from p19Arf mutant mice and p16Ink4a/p19Arf compound mutant mice can still enhance multipotency of HSCs in vitro.101, 105 Furthermore, Bmi-1 plays a non-cell autonomous role in the bone marrow microenvironment that does not depend on p16Ink4a or p19Arf. Similarly, deletion of the entire p16/p19 locus in Bmi-1−/− mice does not completely rescue NSC defects in self-renewal capacity.64, 106

The p16/p19-independent requirement for Bmi-1 in ASC populations may be due to the ability of Bmi-1 to regulate the DDR pathway via repression of the cell cycle checkpoint protein Chk2. Deletion of Chk2 in Bmi-1 mice restores hematopoietic stem and progenitor cell function and enhances progenitor cell proliferation. These reports suggest that modulators of chromatin state, such as Bmi-1, are crucial for maintaining the ability of ASCs to integrate and respond to environmental stresses during aging.

Overexpression of p16Ink4a and p19Arf in adult HSCs induced cell cycle arrest and apoptosis via the pRb and the p53-dependent pathway, respectively. Double deletion of the Bmi-1 and p16/p19 genes partially rescued the phenotypes observed in Bmi-1-deficient mice, suggesting that p16Ink4a, p19Arf, and p53 are downstream effectors of Bmi-1 that are involved in the control of the proliferation and survival of HSCs during self-renewing cell divisions.

In cancer, recurrence after optimal treatment has often been a critical clinical limitation indicative of the existence of another emerging stem cell category that evaded the existing therapy, classified as cancer initiating cells (CIC) or cancer stem cells (CSC). Evidence of CSCs from xenograft models and surviving fraction of treated tumors further consolidate this theory. Therefore, the stemness properties of CICs pose a new challenge to existing cancer therapy and from different studies, Bmi-1 surfaces as a bio-signature of these CIC/CSC.110, 111, 112 The complex dynamics of Bmi-1 function ranging from cell cycle regulation, stem cell maintenance to DDR extends beyond its capacity as a transcriptional repressor of the Ink/Arf pathway. It can be speculated that as future research brings into light new interactors of Bmi-1, many other cellular processes would be discovered in which Bmi-1 plays an important role.

Cancer

As previously noted, Bmi-1 was first identified as a Myc-cooperating oncogene in murine B- and T-cell lymphomas.61, 74, 113, 114 Several recent studies have suggested that in human cancers, Bmi-1 is often overexpressed and acts as an oncogene to promote carcinogenesis including prostate, lung, ovarian, urinary bladder, lymphoma, mesothelioma, medulloblastoma, glioma, acute myeloid leukemia and breast cancer. Bmi-1 overexpression drives stem-like properties associated with induction of EMT that promotes invasion, metastasis, and poor prognosis.51, 61 This section summarizes (Table 2) the critical roles of Bmi-1 in all reported types of cancer to date.

Table 2

Known roles of Bmi-1 in cancer.

Cancer	Role of Bmi-1	Reference
Breast	Bmi-1 plays a crucial role in invasion and metastasis by modulating the Akt/GSK-3b/Snail pathway and the expression of EMT markers in breast cancer	130,131
Colorectal	Bmi-1 regulates histone ubiquitination for colon cancer proliferation in vitro and in vivo	132,26
Glioblastoma	Bmi-1 overexpressed in human glioblastoma tumors and highly enriched in tumor-initiating CD133+ stem cells	120
Head and neck	Bmi-1 directly regulates the EMT regulator, Twist1	128
Hepatic	Bmi-1 is upregulated in human hepatocellular carcinoma in an Ink4a/Arf-independent manner in liver cancer development	72
Intestine	Bmi-1 deficiency impairs the progression and maintenance of small intestinal tumors in a cell autonomous and highly Arf-dependent manner.	134
Leukemia	Bmi-1 is highly expressed in M0-subtype acute myeloid leukemia	135, 136
Lung	Bmi-1 is required for the self-renewal of the lung epithelial stem cells and bronchioalveolar stem cells	138, 139
Lymphoma	Bmi-1 can contribute to lymphomagenesis in the T and B cell lineages and collaborate with the Myc gene in tumor development	152
Medullo-blastomas	Bmi-1 is strongly expressed in proliferating cerebellar precursor cells in mice and humans.	117
Naso-pharyngeal carcinoma	Bmi-1 is highly overexpressed which lead to the induction of telomerase activity, reduction of p16Ink4a expression, and immortalization of nasopharyngeal epithelial cells	125
Ovary	Bmi-1 protein is highly expressed in ovarian epithelial cancer tissues	31, 88
Pancreatic cancer	Bmi-1 is overexpressed in human pancreatic cancer	153
Prostate	Bmi-1 is a crucial regulator of self-renewal in adult prostate cells and plays important roles in prostate cancer initiation and progression	93
Skin	Bmi-1 levels are markedly elevated in epidermis-derived cell lines and in epidermal squamous cell carcinoma	140
Tongue	Bmi-1 is abnormally overexpressed in tongue cancers, which is associated with cervical node metastasis.	141

This table gives a brief overview of the reported functions of Bmi-1 in progression and maintenance of human cancers.

EMT – epithelial–mesenchymal transition.

Glioblastoma: Bmi-1 has been shown to be essential for the proliferation and self-renewal of the NSCs of the sub-ventricular zone.18, 54, 64, 100, 106, 116, 117 Also, Bmi-1 is necessary for the propagation of leukemic stem cells and is expressed in glioblastoma stem cells.74, 118 Häyry et al, have shown that Bmi-1 is expressed in all histological types of gliomas and that relative protein expression is a novel independent prognostic marker in oligodendroglial tumors. Bmi-1 is overexpressed in human glioblastomas and is highly enriched in the tumor-initiating CD133+ stem cells. Knockdown of Bmi-1 completely prevented brain tumor formation in mice. miR128 has also been shown to negatively regulate Bmi-1 expression and inhibits self-renewal of glioma.

Medulloblastomas: Bmi-1 is strongly expressed in proliferating cerebellar precursor cells in mice and humans. Overexpression of Bmi-1 promotes cell proliferation and is required for the hedgehog pathway-driven tumorigenesis in medulloblastomas. Sonic hedgehog (Shh) modulates Bmi-1 in childhood medulloblastoma brain tumor-initiating cells. Bmi-1 expression positively correlates with increasing Shh ligand concentrations.

Ovarian cancer: Bmi-1 is highly expressed in ovarian epithelial cancer tissues, and its expression level correlates with histological grade and clinical phase of the patients. We had previously found that inhibition of the Shh pathway by cyclopamine inhibited sub-cutaneous ovarian tumor growth and potently downregulated Bmi-1 at the protein level. Elevation of Bmi-1 expression is closely correlated to the increased telomerase activity. miR-15a and miR-16, which are under expressed in ovarian cell lines and in primary ovarian tissues, directly target the 3′ untranslated region (UTR) and significantly correlate with Bmi-1 protein levels in ovarian cancer patients and cell lines. Furthermore, Bmi-1 protein levels are downregulated in response to miR-15a or miR-16 expression and cause significant reduction in ovarian cancer cell proliferation and clonal growth.

Prostate cancer:Bmi-1 is overexpressed in prostate cancer with adverse pathologic and clinical features. Tumors with higher Gleason scores have a significant upregulation of Bmi-1, while the presence of Bmi-1 in lower grade prostate cancer samples is highly predictive for prostate-specific antigen recurrence. Microarray meta-analyses have found that the presence of Bmi-1 in prostate cancer specimens often indicates metastatic disease and a high probability of unfavorable therapeutic outcome. Bmi-1 has been shown enriched in a population of prostate cancer cells with higher tumor initiating capacities. Bmi-1 inhibition protects prostate cells from FGF10 driven hyperplasia and slows the growth of aggressive PTEN-deletion induced prostate cancer.

Nasopharyngeal carcinoma: Bmi-1 is overexpressed in nasopharyngeal carcinoma cell lines at both mRNA and protein levels. Overexpression of Bmi-1 was also observed in a significant number of nasopharyngeal carcinoma tumors, which correlated with advanced invasive stage of the tumor progression and poor prognosis. Overexpression of Bmi-1 led to induction of telomerase activity, reduction of p16Ink4a expression and immortalization of nasopharyngeal epithelial cells. Bmi-1 plays an important role in the pathogenesis of nasopharyngeal carcinoma by inducing EMT partially by targeting the tumor suppressor PTEN, thus activating the PI3K/Akt pathway. Upregulation of Bmi-1 led to the stabilization of Snail, a transcriptional repressor associated with EMT, via modulation of PI3K/Akt/GSK-3β signaling.

Head and neck cancer: Bmi-1 mediates its diverse effects through upregulation of the mitotic kinase Aurora A, which is encoded by the AURKA gene. During Bmi-1-overexpression, the β-catenin/TCF4 complex regulates the transcription of AURKA. In patients with head and neck cancers, increased levels of both Twist1 and Bmi-1 correlate with downregulation of E-cadherin and p16Ink4a, and are associated with worse prognosis. In addition, in head and neck squamous cell carcinoma (HNSCC) a CD44+ fraction comprising of less than 10% of the tumor significantly expresses nuclear Bmi-1 and demonstrates stem-like properties by giving rise to tumor in vivo.

Breast cancer: Breast cancer shows a high prevalence of Bmi-1 expression, which is significantly correlated with aggressive features and unfavorable prognosis. Bmi-1 plays a crucial role in invasion and metastasis by modulating the Akt/GSK-3b/Snail pathway and the expression of EMT markers in breast cancer. Bmi-1 promotes the invasion and metastasis of human breast cancer. Bmi-1 is critical to the oncogenic behavior of several established breast cancer cell lines in vitro and in vivo. Most importantly, the collaboration of Bmi-1 and H-RAS in human mammary epithelial cells leads to a highly aggressive phenotype that includes increased spontaneous metastasis to the liver and spleen, and novel metastasis to the brain.

Colorectal cancer: Bmi-1 regulates histone ubiquitination in primary human colorectal cancer cells which plays an important role in colon cancer proliferation in vitro and in vivo. Kreso et al, recently reported for the first time that the stemness function of CICs could be targeted with a small-molecule inhibitor of Bmi-1. In human colorectal cancer, CIC function is dependent on the canonical self-renewal regulator Bmi-1. Downregulation of Bmi-1 inhibits the self-renewal property of colorectal CICs, and thus abrogates their tumorigenic potential. Bmi-1 inhibitor treatment in primary colorectal cancer xenografts also resulted in colorectal CIC loss with long-term and irreversible impairment of tumor growth. Targeting the Bmi-1-related self-renewal machinery provides the framework for clinical evaluation of anti-Bmi-1 therapy not only in colorectal cancer but other cancers such as ovarian cancer which are characterized by frequent relapse after chemotherapy.

Hepatocellular carcinoma: Bmi-1 is upregulated in HCC. Bmi-1 can cooperate with other oncogenic signals to promote hepatic carcinogenesis in vivo. Bmi-1 functions independent of Ink4A/Arf repression in liver cancer development.

Intestinal cancer: Bmi-1 deficiency impairs the progression and maintenance of small intestinal tumors in a cell autonomous and highly Arf-dependent manner. Bmi-1 loss reduces both the number and size of small intestinal adenomas.

Leukemia: High expression of Bmi-1 in acute myeloid leukemia cells is associated with an unfavorable prognosis. Expression of Bmi-1 is required for maintenance and self-renewal of normal and leukemic stem and progenitor cells, and protects cells against oxidative stress. Also, Bmi-1 has an essential role in maintaining the self-renewing capacity of leukemic stem cells.

Lung cancer: Bmi-1 is required for the self-renewal of ASCs including the lung epithelial stem cells, bronchioalveolar stem cells (BASCs).138, 139Bmi-1 knockout mice exhibited an impaired ability to repair Clara cell injury that was associated with failure of BASC expansion in vivo.14, 138

Skin cancer: Bmi-1 plays an important role in maintaining proliferation of basal keratinocytes and in maintaining the viability. Bmi-1 levels are distinctly elevated in immortalized and transformed epidermis-derived cell lines and in epidermal squamous cell carcinoma of suprabasal differentiating keratinocytes.

Tongue cancer: Bmi-1 is aberrantly overexpressed in a significant portion of tongue cancers. Elevated Bmi-1 is associated with cervical node metastasis. Bmi-1 serves as a key driver with multiple oncogenic functions during tongue cancer progression and as a novel biomarker for diagnosis and prognostic prediction for patients.

The exhaustive above list of malignancies where Bmi-1 acts as an oncoprotein can be expected to be expanded as research progresses. Given the wide variety of cancers ranging from solid tumors to glioblastoma to leukemia, where Bmi-1 is implicated and its involvement in maintenance of CSC's that are chemoresistant makes Bmi-1 a potential candidate for drug therapy.

Conclusion and future directions

Bmi-1 is at an important crossroad in at least 16 different types of cancer and stands out as a promising target in the small list of genes known to regulate CSC function. Thus, Bmi-1 is an important new target for therapy in malignancies characterized by overexpression of Bmi-1. However, since no direct enzymatic activity of Bmi-1 has yet been established, developing a small molecule inhibitor that directly targets Bmi-1 poses a pharmacological challenge.

However in principle, several independent groups have investigated the effect of reducing Bmi-1 levels in vitro and in vivo in different cancers ranging from ovarian to prostrate and these studies have validated Bmi-1 as a therapeutic target. Our previous study on ovarian cancer has argued in favor of anti-Bmi-1 therapy in clinical settings due to enhanced cisplatin sensitivity upon Bmi-1 silencing. Also downregulation of Bmi-1 leads to de-repression of Ink4a, which encodes tumor suppressors p16Ink and p19Arf that regulate senescence and apoptosis. Activation of these pathways has been invoked as important tumor suppressors, because these pathways act as potent inhibitors of proliferation or propagation of damaged cells. In addition, we posit that cisplatin and Bmi-1 act on similar pathways affecting mitochondrial function and/or through increased ROS generation, causing DNA damage augmenting the signal initiating apoptosis. As noted above in the context of various cancers, different miRs target the Bmi-1 mRNA, and we have shown that miR15a/16 significantly reduce Bmi-1 levels and subsequent clonal growth in ovarian cancer cells.In vivo silencing of Bmi-1 by siRNA delivered using DOPC (1,2-dioleoyl-sn-glycero-3-phosphatidylc holine) nanoliposomes in the orthotopic A2780-CP20 mouse model resulted in significant reduction in tumor weight and nodules compared to the control siRNA group. Combination therapy with Bmi-1 siRNA and cisplatin resulted in even greater reduction in tumor weight and nodule. Therefore, though siRNA or miRNA approaches against Bmi-1 might prove useful in therapy, delivery and off-target effects remain of considerable concern. In this context, several known drugs have been reported to reduce Bmi-1 expression. For example, Bommi et al, and Jung et al, independently investigated the effects of HDACi on Bmi-1 expression and downstream targets. HDACi treatment downregulated PcG genes such as Bmi-1, EZH2 and SUZ12 in senescent mesenchymal stem cells. This was associated with hypophosphorylation of Rb, which causes Rb to bind and decrease the transcriptional activity of E2F and cellular senescence by p16Ink4a regulation. Blocking Bmi-1 expression by HDACi in immortal non-transformed breast epithelial cells and breast cancer cells was accompanied by a decrease in histone-2A Lys119 ubiquitination (H2AK119Ub), de-repression of growth inhibitory genes and putative tumor suppressors, which are known to be silenced by PcG proteins and PRCs.

Recently, the drug Artemisinin was also shown to inhibit the expression of Bmi-1. Artemisinin and its derivatives are particularly useful for the treatment of resistant Plasmodium falciparum malarial parasites. This drug has an endoperoxide group that is activated by intraparasitic heme–iron to form free radicals, which kill malarial parasites by alkylating biomolecules. Artemisinin inhibited Bmi-1 at both protein and transcriptional levels. Bmi-1 knockdown made the cells more sensitive to Artemisinin with an increase in accumulation at the G1-phase of the cell cycle. However, none of these drugs can be claimed to be a specific Bmi-1 inhibitor and therefore run the risk of bystander effect when evaluated from a clinical perspective.

In this regard PTC Therapeutics (NJ) has attempted to exploit the possible post-transcriptional regulation of Bmi-1 in a bid to screen for Bmi-1 specific drugs. The Bmi-1 3′-UTR contains multiple A–U rich elements that can significantly upregulate reporter gene expression, while its 5′-UTR contains a strong IRES activity. High-throughput screening using compounds that selectively inhibited 5′- and 3′- UTR-mediated Bmi-1 reporter expression identified PTC-209, which subsequently inhibited endogenous Bmi-1 expression in human colorectal HCT116 and human fibrosarcoma HT1080 tumor cells in a dose- and time- dependent manner (IC50 at about 0.5 μM). Cytotoxicity was ruled out since PTC-209 did not inhibit cell growth or viability in HEK293 human embryonic kidney cells after overnight treatment and had limited effects on cell proliferation in HT1080 cells after a 48-h treatment. That PTC-209 modulated the Bmi-1-PRC1 complex activity was evident from reduced global ubiquitinated histone H2A with no effect on total H2A or RING1A levels. PTC-209 selectively lowered Bmi-1 levels and decreased colorectal tumor cell growth. Further, unlike the genetic manipulation, PTC-209 provided the control to modulate the length and extent of Bmi-1 inhibition through the addition or removal of the inhibitor, a critical tool to further investigate the effects of Bmi-1 function in various cancers. Thus the future of anti-Bmi-1 therapy holds promise and development of kinase specific inhibitors that affect specific phosphorylation sites on Bmi-1 can be envisioned.

Conflicts of interest

None to declare.