The Molecular Basis of Ubiquitin-Conjugating Enzymes (E2s) as a Potential Target for Cancer Therapy.

Ubiquitin-conjugating enzymes (E2s) are one of the three enzymes required by the ubiquitin-proteasome pathway to connect activated ubiquitin to target proteins via ubiquitin ligases. E2s determine the connection type of the ubiquitin chains, and different types of ubiquitin chains regulate the stability and activity of substrate proteins. Thus, E2s participate in the regulation of a variety of biological processes. In recent years, the importance of E2s in human health and diseases has been particularly emphasized. Studies have shown that E2s are dysregulated in variety of cancers, thus it might be a potential therapeutic target. However, the molecular basis of E2s as a therapeutic target has not been described systematically. We reviewed this issue from the perspective of the special position and role of E2s in the ubiquitin-proteasome pathway, the structure of E2s and biological processes they are involved in. In addition, the inhibitors and microRNAs targeting E2s are also summarized. This article not only provides a direction for the development of effective drugs but also lays a foundation for further study on this enzyme in the future.

1. Introduction

The 2004 Nobel Prize in Chemistry was awarded to three scientists (Aron Ciechanover, Avaram Heshko and Irwin Rose) for their discovery of the mechanism of protein degradation regulated by ubiquitin (Ub). They found the same class of peptides in mammals, bacteria and plants, whose structures and properties were very similar. They named it Ub because of its widespread existence [1]. Ub has the property of forming stable chemical bonds with other proteins to regulate their stability, activity or position [2]. Ub modifies substrate proteins through the ubiquitin-proteasome pathway (UPP), which requires three key enzymes—Ubiquitin-activating enzyme (E1), ubiquitin-conjugating enzyme (E2), and ubiquitin ligase (E3), to hydrolyze the target proteins of ubiquitination in cells to maintain protein homeostasis [3].

Residing at the center of the cascade, E2s largely determine Ub chain topology and are responsible for recruiting E3 ligases and their substrates [4]. The relationship between E2s and human cancer has been studied extensively. Ullah et al. [5] showed that increased expression or mutation of UBE2O is common in breast cancer (BC), gastric cancer (GC), renal carcinoma (RC) and ovarian cancer (OC). The UBE2C mRNA or protein can hardly be detected in normal tissues; however, it is abnormally elevated in diseases such as cerebral cancer, lung cancer (LC), leukemia, lymphoma, GC, BC, colon cancer (CC) and hepatocellular carcinoma (HCC) [6,7,8,9]. Even UBE2C transgenic mice are more likely to develop spontaneous tumors and tumors induced by carcinogens [10]. Wu et al. [11] found that UBE2N is related to the low overall survival rate of human BC and is directly involved in the process of metastasis, which is necessary for lung colonization and the survival and proliferation of established metastatic lesions. Cases of the abnormal expression of other E2 members in different cancer cells or tissues are also widespread. This not only affects the protein turnover of cancer cells, but also indirectly regulates the proliferation, metastasis, anti-apoptosis and drug resistance of cancer cells by participating in certain biological processes. Although researchers are committed to studying the roles of E2s in various diseases and constantly emphasize the potential of E2s as a therapeutic target, the molecular basis of E2s as a potential therapeutic target for cancer has not been described systematically. A newly published review classified systematically all the reported small molecular inhibitors of the basic components of UPP, including E1, E2, E3, 20s proteasome catalytic core particles and 19s proteasome catalytic core particles, as well as their mechanisms of action and limitations [12]; however, the inhibitors and microRNAs (miRNAs) targeting E2s were not fully summarized. Therefore, we reviewed the literature in the past five years to cover these two aspects. We discuss the molecular basis of E2s as a target for cancer therapy from the special position and functions of E2s in UPP, the structure of E2s and biological processes they are participated in, and the efforts made to develop corresponding inhibitors. Researchers can select E2 as a specific target and consider the possible positive and negative effects according to the biological processes it participates in, allowing them to develop effective inhibitors with few side effects to control the occurrence and development of cancer.

2. The Position of E2 in UPP

The UPP comprises Ub, E1, E2, E3, 26S proteasome, deubiquitinating enzymes (DUBs) and target proteins [13]. It exists widely in eukaryotes as well as in prokaryotes, and is an important pathway for selective protein degradation in organisms. The UPP involves two consecutive processes: The ubiquitination system ubiquitinates the substrate proteins and 26S proteasome degrades ubiquitinated target proteins [14]. First, under the energy supply of adenosine-triphosphate (ATP), the C-glycine residue of Ub forms a high energy thioester bond with the cysteine residue of E1. Later, E1 connects the activated Ub to E2 through the intermediate product of Ub adenylation to form the E2-Ub sulfhydryl ester. Although Ub can be transferred directly or indirectly from E2 to the substrate, E3 is usually needed to identify specific substrates. Through a E3 enzyme, Ub is transferred from the thioester intermediate to the ε amino group of the target protein (lysine residue) to form an isopeptide bond and then subsequently activates the Ub to connect the 48th lysine residue of the previous Ub molecule to form a signal. This polyubiquitin (polyUb) chain is recognized and degraded by proteasome [15,16] (Figure 1).

Figure 1

A schematic diagram of the ubiquitin-proteasome pathway (refer to [13]). Ubiquitin (Ub) is activated by ubiquitin-activating enzyme in an adenosine-triphosphate-dependent manner. Ubiquitin-activating enzyme hydrolyzes adenosine-triphosphate and forms a complex with Ub. Subsequently, Ub is transferred to one of many different E2s. In some reactions, E2 (UBE2O) can directly ubiquitinate the substrate, while others need the help of ubiquitin ligases (E3s). E3s are currently categorized into three families, (i) Homologous to E6-associated Protein C-terminus (HECT), (ii) Really Interesting New Gene (RING), and (iii) U-box Domain [25]. The Cullin-RING ligases (CRLs), APC/C ligase, and RING-Between-RING ligases (RBRs) all belong to RING E3s. Ubiquitination of substrates occur as mentioned in the three ways: Monoubiquitination, multi-monoubiquitination, and polyubiquitination (including linear polyubiquitination and branched polyubiquitination).

E2 are multi-functional enzymes that primarily engage in two types of reactions with a simple active site in the UPP: (1) Transthiolation (transfer from a thioester to a thiol group) and (2) Aminolysis (transfer from a thioester to an amino group). Most E2s can interact with E1 and one or more E3s [17], providing a binding platform for E1, E3, and activated Ub/Ub-like (Ubl). Some E2s also play a role outside the traditional Ub transport pathway by regulating the activity of other enzymes [18]. It should be pointed out that Ub contains seven different lysine residues (Lys6, Lys11, Lys27, Lys29, Lys33, Lys48, and Lys63), any of which can be covalently linked with other Ub molecules. Besides, the N-terminal (N-) methionine (M1) of Ub is also a site for covalent binding of other Ubs to form M1-linked linear ubiquitylation [19]. So, the type of these Ub chains and the fate of substrate proteins are determined by E2s. PolyUbs can be formed through the same Ub linkage (homotypic chains) or a combination of different lysine linkages, resulting in mixed or branched structures (heterotypic chains). It is only through recognition of these different Ub structures by Ub-binding proteins (UBPs) that the intracellular fate of the protein is determined [20]. A branched Lys11/Lys48 chain in heterotypic chains is considered to be a better signal for proteasome degradation [21]. Generally speaking, Lys48 and Lys11 chains are further involved in proteasome degradation. Proteasome shuttling factors preferentially bind Lys48 chains compared with Lys11 chains. M1-linked ubiquitin chains, Lys63 and Lys6 chains are usually involved in non-proteolytic processes, such as immune homoeostasis [22], DNA repair, signal transduction, and endosomal-lysosomal degradation [23]. The Lys11 chain is less studied than the Lys48 or Lys63 chain, but it seems to serve as a degradation signal for anaphase-promoting complex/cyclosome (APC/C) substrates in the regulation of cell division [24]. The functions of other connection types of Ub chains are not entirely clear.

3. The Structure and Classification of E2

To date, 1635 E2s have been identified in eukaryotic genomes and about 40 E2s in human have been identified to be involved in the transfer of Ub/Ubl proteins (e.g., small ubiquitin-like modifier (SUMO) and NEDD8), while other eukaryotic genome E2 families have 16–35 members [26]. Their names consist of the designation ubiquitin enzyme E2 (UBE2) followed by a serial capital letter according to their consecutive discovery. Most E2s have a highly conserved ubiquitin-conjugating region comprising 150–200 amino acids, known as the UBC domain, which binds Ub/Ubl proteins activated by ATP (Figure 2A). This domain adopts an α/β-fold, typically with four α-helices and a four stranded β-sheets (Figure 2B). The UBC domain is embellished with functionally important insertions, such as UBE2R1 or UBE2G2. Moreover, a few E2s have an additional structured domain linked to their UBC domain (e.g., UBE2K) or are part of large multi-domain proteins (e.g., UBE2O) [27]. Ubiquitin-conjugating enzyme variant (UEV) exhibits high similarity with E2s both in structure and amino acid sequence, but lacks the UBC domain and the active-site cysteine residue, and thus is catalytically inactive [28]. The E2 family has been divided into four classes: Class I, UBC domain only; class II, UBC domain plus an N- extension; class III, UBC plus a C- extension; and class IV, UBC plus both N- and C- extensions [29]. These extra domains not only create E2s of diverse molecular size, including the largest E2, BIRC6 (4857 amino acids), but also can govern intracellular localization, confer regulatory properties, and enable specific interactions with particular E3s [30]. Although the shallow and exposed nature of the catalytic site make it difficult to target the site directly with small molecules, the distinct regions in which E2s are involved in many protein-protein interactions raise the possibility of additional modes of inhibition [31].

Figure 2

(A) The alignment of UBE2T and UBE2I (Ubl). The three dimensional (3D) structure of UBE2T is shown in green, while UBE2I is shown in yellow, indicating that the structure of E2 family is conserved. UBE2T has a C-terminal extension, which belongs to Class III, while UBE2I has no C- and N- extensions, and so belongs to Class I, which are consistent with the summary shown in Table 1 (B) The 3D structure of UBE2T. We marked four α-helixes and four β-folds with white letters. N-term and C-term refer to the N- and C-termini of UBE2T, respectively. The main sites of interaction between UBE2T and E1 and E3 are S1 and S2, respectively, and the active site cysteine (86) is highlighted in red. B1 is opposite to the active site of UBE2T, which is called the ‘backside.’ Backside binding between E2 and Ub or SUMO contributes to chain building activities or regulates E2 activities via allostery [32]. The 3D structures of UBE2T and UBE2I were downloaded from http://www.rcsb.org/ (accessed on 20 November 2020), numbered 5NGZ and 1A3S, respectively. PyMOL software was used to align them, and the prediction of the active site was carried out using http://www.ebi.ac.uk/interpro/result/InterProScan/iprscan5-R20200618-032207-0413-15289371-p2m/ (accessed on 20 November 2020).

4. Biological Processes Involving E2s

4.1. DNA Repair Pathway

Certain proteins are ubiquitinated by radiation or treatment with DNA damaging agents, including proliferating cell nuclear antigen (PCNA), histone H2A and its variant H2A(X), 9-1-1 complex, Fanconi (FA) pathway proteins FANCD2 and FANCI, and replication factor 2 [127] (Figure 3). The pathways of E2s involved in DNA damage repair include: DNA translesion synthesis (TLS) and error free pathway targeting PCNA, DNA double strand break repair (DSBR) and the FA pathway centered on H2A(X) [33]. In addition, some E2 members are involved in other types of DNA repair processes. The SUMOylation of Xerderma pigmentosum C by UBE2I is to participate in nucleotide excision repair (NER) [128]. UBE2I also plays an important role in DNA-protein crosslinks (DPCs) repair by subsequent proteasome hydrolysis of SUMOylation TOP1/TOP2-DPC (Topoisomerase I/II-DNA-protein crosslink), which repairs the inhibition of DNA metabolism caused by the persistence of TOP (Topoisomerase) [129]. RAD6 mutants are sensitive to alkylating agents, and alkylating agent-induced DNA damage is repaired by base excision repair (BER) pathway, indicating that RAD6 may be involved in BER. UBE2K is involved in these two different repair processes [130]. Damaged DNA can lead to cell cycle arrest and induce the process of DNA repair. Once the damage is repaired, the cells that stop the checkpoint will resume the cell cycle. The accumulation of unrepaired DNA usually triggers the activation of multiple cell death or carcinogenic pathways, resulting in cell death, senescence, or cancer [131].

Figure 3

E2s participate in the DNA repair pathway. (A) E2 ubiquitinates proliferating cell nuclear antigen (PCNA) to participate in the DNA replication and repair process. (B) E2 ubiquitinates the FANCD2 and FANCI complex to participate in the FA pathway. (C) E2 ubiquitinates H2A(X) to participate in the DNA replication and repair process. UBE2D3 can also participate in the above (A,C) processes [151].

UBE2N cooperates with UBE2V2 to modify PCNA to participate in DNA replication and repair pathways [132]. DNA damage induces monoubiquitination at Lys164 of PCNA, which is catalyzed by UBA1, RAD6, and RAD18 (which also involved in the activation of FA pathway). DNA damage induces nuclear entry of UBE2N and UBE2V2, which are recruited into chromatin by RAD5, where they catalyze PCNA to form a Lys63-linked polyUb chain. RAD6 binds to RAD18 to regulate the TLS pathway of mutant DNA in response to genomic damage, including that induced by chemotherapy and radiotherapy. In the absence of DNA damaging agent, PCNA is modified by SUMO in the S phase, preventing post-replication repair enzymes from being recruited into an inappropriate period of the cell cycle [133] (Figure 3A). UBE2N can also interact with RNF8 and RNF168 to participate in the DNA injury response. OTU domain-containing ubiquitin aldehyde binding protein 1 (OTUB1) regulates DNA repair by hydrolyzing the UBE2N-mediated Lys63 polyUb chain [134].

DSBs can be repaired by homologous recombination (HR) or non-homologous end joining (NHEJ). HR plays an important role in the S/G2 phase of the cell cycle, while NHEJ can function in all phases of the cell cycle [135]. UBE2S was found to be associated with the components of the NHEJ complex and participates in the NHEJ-mediated DNA repair process [136]. The MRN complex (MRE11, RAD50, NBS1) detects DNA DSBs and forms a complex with phosphorylated mediator of DNA damage checkpoint protein 1 (MDC1) and histone H2AX. MDC1 recruits RNF8/UBE2N/UBE2V2, to make H2AX form a Lys63-linked polyUb chain. RAP80 recognizes the Lys63 polyUb chain on H2AX and forms a complex with ABRA1 (Abraxas), BRCC36, breast cancer-1 (BRCA1), and BARD to participate in HR (Figure 3C). OTUB1 inhibits the process via deubiquitination of UBE2N. By collaborating with the heterodimeric E3 ligase RNF20/RNF40, RAD6 catalyzes the monoubiquitination of H2B to participate in the regulation of DNA damage repair [137].

UBE2T (also known as FANCT) is first identified in a case of FA, and catalyzes the monoubiquitination of the FANCD2 and FANCI complex with FANCL (RING-type E3). Then, they cluster in DNA interstrand cross-link (ICL) lesions by binding with unknown X1 or X2 in the DNA repair process [138] (Figure 3B). The RAD18/RAD6 complex is also crucial to activate the FA pathway. When the repair process is completed, the FANCD2 and FANCI complex is deubiquitylated and dissociated from the repaired ICL site by the USP1-UAF1 complex and is then released from the DNA [139]. The destruction of UBE2T expression leads to FA (a DNA repair defect) by affecting the damage repair response of DNA ICL. On the one hand, it increases the risk of early cancer in adults [140]; on the other hand, it increases the sensitivity of cancer cells to cross-linking agents [141]. Lyakhovich [142] showed that knocking down FANCD2 increased the sensitivity of cancer cells (BC, Bladder, or LC cell lines) to mitomycin C (MMC) and to a lesser extent, to gamma-rays. Importantly, those cell lines with significant FANCD2 depletion revealed a decreased recurrence capacity. Ramaeker [143] showed that hypoxia can rapidly and forcefully reduce the level of UBE2T mRNA in cancer cell lines, thus greatly increasing the sensitivity of cancer cells to MMC therapy. Therefore, to reduce the risk of cancer, it is necessary to ensure stable levels of UBE2T and other proteins involved in the FA pathway. To treat patients with cancer, the combination of DNA cross-linking agents (e.g., MMC, Cisplatin (DDP)) with inhibitors of the FA pathway might kill cancer cells by preventing them from replicating and repairing. UBE2T can also promote the removal of DSBs in the process of DNA HR repair [144].

Overall, in normal cells, E2s are involved in DNA repair and restart of damaged DNA replication forks to maintain genomic integrity and reduce the incidence of cancer [145]. The increased expression and activation of DNA damage response signals and repair genes are the reasons for the resistance of cancer cells to radiotherapy [146]. Downregulation of UBE2S expression in Glioblastoma (GBM) suppressed NHEJ-mediated DSBR, and made GBM cells more sensitive to radiotherapy [136]. RAD6 regulates mutagenic TLS and FA in response to various genomic insults, including chemo and radiation therapy [147]. TZ9 (a RAD6-specific small molecule inhibitor) treatment of triple negative breast cancer (TNBC) and OC cells weakens the DNA repair signal of these cells, thus increasing the sensitivity of drug-resistant cancer cells to carplatin [148]. UBE2B regulates the sensitivity of nasopharyngeal carcinoma (NPC) cells to carmustine (BCNU) by ubiquitination of MGMT (a DNA repair enzyme) [149]. UBE2D3 had the opposite effect, and its downregulation promoted DNA damage repair in esophageal cancer cells and enhanced the radiation resistance of cancer cells [150]. We know that NHEJ-mediated DSBR exists in all stages of the cell cycle, and the repair process is fast but inaccurate. Although HR-mediated DSBR only exists in the S/G2 phase of the cell cycle, the repair process is complex but accurate. Therefore, UBE2S and UBE2N, which are involved in these two processes, can be considered as anticancer targets. In view of the ineffectiveness of radiotherapy and emergence of chemotherapy resistance, it is urgent to develop inhibitors of DNA damage repair signals. Combining the inhibitors with radiotherapy and chemotherapeutic drugs mighty increase the effectiveness of cancer treatment. This requires further study.

4.2. Cell Cycle

Cell cycle progression is monitored by a set of checkpoints G1/S, G2/M, and spindle-assembly checkpoint (SAC) that push cells forward from one stage to the next [35], and their transformation depend largely on the UPP (Figure 4A). Kinase inhibition protein p27 (p27Kip1), as an inhibitor of cyclin-dependent kinase (CDK), can be ubiquitinated by UBE2D and UBE2R1 in the transition of G1max to S phase, thus alleviating the inhibition of the CDK4/CDK6 complex [152]. The genes regulated by p27Kip1 are closely associated with poor cancer survival, indicating that p27Kip1 is associated with cancer progression [153]. UBE2D3 is also the initial ubiquitination enzyme for key regulatory molecules such as cell cyclin D1 (CCND1), inhibitor of nuclear factor kappa B (IκB), p53, and MDM2 [154]. UBE2R1 and UBE2R2 participate in the extension of cell cyclin E (CCNE) ubiquitin chain [155]. UBE2C has been proposed to be rate-limiting in the late G1 phase, when it is required to degrade cell cyclin A by APC/C to prevent premature DNA replication [156]. RAD6 influences the transcription of CDK1 by increasing monoubiquitinylation of H2B and trimethylation of H3K4 in the CDK1 promoter region. Therefore, RAD6 promotes G1/S phase transition and cell proliferation [157]. In addition, SUMO also plays a significant role in the cell cycle, and CDK1, CDK9, CDK11, and CCNE have been identified as targets of SUMO [158]. In GBM cells, SUMOylation of CDK6 can prevent its ubiquitination and degradation, and ensure its existence in the process of G1/S transformation [159]. In the transition of G/M phase, this process is promoted by ubiquitination of WEE1 [160].

Figure 4

(A) E2s participate in the cell cycle process. (B) E2s regulate the cell cycle and apoptosis process by ubiquitinating p53. p53 upregulated modulator of apoptosis (PUMA) and BCL2-associated X (BAX) can induce apoptosis through increasing mitochondrial outer membrane permeability.

SAC ensures an equal distribution of chromosomes to daughter cells during mitosis [161]. Improper SAC results in malignancies or birth defects. APC/C (SAC inhibits APC/C) is also one of the determinants of precise division of genetic material during mitosis [162]. The inhibition of APC/C by SAC is inhibited by the tetramer binding of mitotic checkpoint complex (MCC) formed by cell division cycle 20 (CDC20), MAD2, BUBR1, and BUB3 in the G2/S phase (Figure 4A). UBE2C has been reported to be required to dissociate the MAD2-CDC20 complex by ubiquitylating CDC20, thus releasing the MCC [163]. Inactive APC/C is activated by binding with free CDC20, and then the activated APC/C ubiquitinates securin and cell cyclin B1 (CCNB1) via UBE2C and UBE2S [164]. Subsequently, securin and CCNB1 are ubiquitinated and degraded rapidly, resulting in the transition from metaphase to anaphase of mitosis [165]. The recognition of different ubiquitin chains by proteasomes gives different “priority” to the degradation of substrates. The heteromorphic Lys11/Lys48 chains mediated by UBE2C and UBE2S in the cell cycle are vital for the orderly and accurate progress of the cell cycle [166]. The formation of heterotypic chains with multiple different lysine linkages on CCNB1 is determined by the concentration of UBE2C within the APC/C Ub reaction. Low concentrations of UBE2C form heterotypic chains predominantly containing Lys11/Lys48 linkages, but at high concentrations, UBE2C forms complex chains with six different Ub linkages. UBE2C or UBE2D co-operate with APC/C for the initial ubiquitin attachment to substrates, while UBE2S co-operates with APC/C for subsequent ubiquitin attachments, producing Lys11 chains [167].

In addition, UBE2C, UBE2D2, UBE2D3 [168], UBE2N, UBE2Q1, UBE2S, and UBE2T [169] can affect the stability and activity of p53 protein to mediate cell cycle arrest. p53 acts as a homotetramer transcription factor, regulating the expression of genes including transactivation of its target genes, including cyclin dependent kinase inhibitor 1A (CDKN1A, also known as p21/Cip1), GADD45, and stratifin (SFN, also known as 14-3-3σ) or inhibits CDC2 and CCNB1 expression [170]. Mutation of p53 upregulates CCND1 and downregulates CDKN1A, leading to a highly active CDK4/CDK6 complex and thus ensuring uninterrupted pancreatic cancer cell division and uncontrolled cell proliferation [171]. Overexpression of UBE2S in HCC functions as an oncogene by increasing the ubiquitination of p53 [172]. HEK293 cells overcame radiation-induced G2/M cell cycle arrest through ubiquitination of p53 via UBE2K. Phosphorylated UBE2K inhibits p53, thereby suppressing the expression of CDKN1A, and sequentially stimulating CCND and CCNE to induce re-entry into the cell cycle. This suggests that UBE2K plays a regulatory role in ultraviolet-induced cell cycle arrest and re-entry [173,174]. Knockdown of UBE2Q1 reduced HCC cell proliferation, promoted apoptosis via induction of GADD45α, and suppressed orthotopic tumorigenicity both in vitro and in vivo [175].

Disorders of cell cycle progression play a key role in the formation and development of cancer, and the abnormal regulation of the cell cycle often leads to the occurrence and development of cancer. UBE2S is highly expressed in melanoma cells and tissues. Treatment of melanoma cells with a short hairpin RNA targeting UBE2S led to cell cycle arrest in the G1/S phase and inhibition of cancer cell growth [176]. UBE2T knockout can significantly inhibit the proliferation and colony formation of bladder cancer cells, induce cell cycle arrest, and increase the rate of apoptosis, which might be related to the fact that UBE2T is the target gene promoted by the E2F transcription factor [177]. Inhibition of UBE2T in GC cells arrested the cell cycle in the G2/M phase, and ultimately inhibited cell proliferation and colony formation [178]. UBE2C and APC/C affect the proliferation rate and cell cycle distribution of esophageal cancer cells by interfering with the level of CCNB [179]. The cell cycle regulator FOXM1 binds to the UBE2C promoter region in esophageal cancer cells and activates its transcription, leading to upregulation of UBE2C expression [180]. Overexpression of UBE2C can also induce epithelial to mesenchyme transition (EMT) related to cancer cell invasion and metastasis through the APC/C complex and Wnt/β-catenin [7], P13K/AKT, and p53 [181] signaling pathways. EMT is closely related to the occurrence and development of cancer. Silencing UBE2C causes pancreatic ductal adenocarcinoma cells to block in the G1/S phase, and reduces the levels of EMT markers (VIM, E-cadherin) [182]. E2s that regulate EMT also include UBE2O, UBE2V1, and UBE2T [183]. Flavopiridol can significantly inhibit the activity of CDKs (1/2/4/6/7) by interacting with the ATP binding pocket on the kinase, thereby causing G1/G2/M phase block. It is a classic non-selective CDK inhibitor and has successfully entered clinical trials [184]. Thus, blocking the cell cycle of malignant cell proliferation-associated diseases, such as cancer, will be the basis for developing new drugs for many years. However, it can be seen from the above that UBE2C and several special E2s promote the progress of cell cycle. At the same time, UBE2N and other E2s regulate p53 to regulate cell cycle. Therefore, the regulation of E2s on cell cycle is complex and extensive, which requires further study of the unique role of single E2 in cancer cell.

4.3. Apoptosis

The UPP plays a key role in the regulation of apoptosis. Currently, three apoptosis pathways are studied, namely the death receptor-mediated pathway, the mitochondria-mediated pathway, and the endoplasmic reticulum pathway [185]. Regulatory factors of apoptosis include B-cell leukemia/lymphoma 2 protein family (BCL2), inhibitor of apoptosis proteins (IAPs), and IκB kinase (IKK) regulatory factors. Some regulatory molecules involved in apoptosis have been identified as proteasome substrates [186]. BIRC6 is a member of the IAP family. Its overexpression prevented apoptosis by ubiquitinating and degrading second mitochondria-derived activator of caspases (SMAC) and caspase 9 in mouse fibroblasts [187]. BIRC6 can also bind to other active caspases, including caspases 3, 6, and 7, and such interactions have been shown to underlie its ability to inhibit the caspase cascade and ultimately apoptosis [188]. Knockout of BIRC6 can block the CRC cell cycle in the S phase and increase apoptosis [189]. High levels of BIRC6 protein are related to poor clinical manifestations of patients with prostate cancer (PCa) [190], non-small cell lung cancer (NSCLC) [191], acute leukemia [192], and epithelial OC [35], which are related to poor prognosis. It can be seen that targeting E2 member BIRC6 in cancer cell can release the inhibition and degradation of caspase activity, thus affecting the survival of cancer cell. Inhibition of apoptosis prevents the death of cancer cells, either associated with carcinogenic initiation or cancer therapy [193]. UBE2O-mediated c-Maf ubiquitination and degradation, which can induce multiple myeloma cell apoptosis [194]. UBE2M promoted osteoarthritis chondrocyte apoptosis by activating the Axin-dependent Wnt/β-catenin pathway [195].

Certain E2s, such as UBE2B, UBE2C, UBE2D, UBE2Q, and BIRC6, function to regulate cell apoptosis through the ubiquitination and degradation of p53. p53 regulates apoptosis by regulating genes such as PUMA, NOXA, BIM, BAX, BCL2, FAS, and IGFBP3 (Figure 4B), and it can also induce cell apoptosis through the death signal receptor protein pathway (TNF receptor and Fas protein) [182]. Suppression of UBE2D can stabilize p53, leading to enhanced apoptosis and markedly inhibited proliferation of human LC cells in a p53-dependent manner [196]. The mutation of BIRC6 led to upregulation of p53, resulting in mitochondrial apoptosis [197]. The upregulation of UBE2D1 in HCC promoted the growth of HCC, which was achieved by mediating the ubiquitination and degradation of p53 [198]. Complete silencing of UBE2I in RAW264.7 cells resulted in apoptosis. Downregulation of UBE2I decreased the level of the BCL2 protein in HepG2 cells and thus caused HCC cell apoptosis [117]. These reports showed that UBE2I is necessary for cancer cell survival. The above studies indicated that multiple E2 members can directly or indirectly regulate the apoptosis of cancer cells. To a large extent, the drug resistance of cancer cells is also based on the resistance to apoptosis. This observation will be useful to develop treatments for diseases such as cancer and abnormal cell proliferation.

4.4. The Wnt/β-Catenin Pathway

Wnt/β-catenin signaling pathway plays an important role in embryonic development [199]. As the core component of this pathway, β-catenin is tightly regulated by post-translational modifications that fine-tune its protein level and optimal activity. β-catenin is phosphorylated by CK1 and GSK-3β and then enters the UPP. Under the combined action of SKP1/CUL1/F-box protein complex-β-transducin repeat-containing protein (SCF-βTrCP) and some E2s, β-catenin is degraded, which stabilize the concentration of β-catenin in the cytoplasm and block the Wnt/β-catenin signaling pathway [200]. As a novel activator of the Wnt/β-catenin signaling pathway, UBE2S modifies β-catenin at Lys19 via a Lys11-linked polyUb chain. This modification promotes β-catenin stabilization through antagonizing its Lys48-linked proteasomal degradation, mediated by the destruction complex/βTrCP signaling [201]. UBE2B can also stabilize β-catenin through the Lys63-linked polyUb chain, and silencing UBE2B can inhibit the transcription activity of β-catenin [202]. This is because UBE2B is the transcription target of β-catenin/T-cell factor. Even if β-catenin is ubiquitinated, it is stable and transcriptionally active, indicating that there is positive feedback regulation between UBE2B and β-catenin [203].

If the activity of E2 or E3 changes, it will destroy the stability of β-catenin. The concentration of β-catenin might increase in the cytoplasm, which in turn activates the Wnt/β-catenin signaling pathway, and ultimately regulates the transcription of target genes C-MYC, CCND1, and matrix metalloproteinase 7 (MMP7) [204]. Overexpression of UBE2S significantly upregulated the expression of β-catenin, CCND1, and MMP7, and the activity of Wnt/β-catenin signaling in A549 cells [205]. In addition, since Wnt/β-catenin signaling is crucial for the activity of epithelial stem cells, it is not surprising that Wnt/β-catenin pathway mutations are frequently observed in carcinomas [206]. The positive regulatory relationship between UBE2S and hypoxia-inducible factor 1α (HIF-1α) in cancer cells might contribute to greater proliferation, angiogenesis, and metastasis of cancer [207]. Overexpression of UBE2S can also activate β-catenin signaling by downregulating SOX6, inhibiting the activity of CCNB1, and promoting the proliferation and migration of endometrial cancer cells [208]. UBE2T downregulation suppressed the activity of the Wnt/β-catenin signaling pathway, which ultimately suppressed NSCLC cell proliferation, migration, and invasion in vitro [209]. The pathway activation and in vitro pro-metastasis effects of UBE2T were blocked using an AKT inhibitor. Therefore, UBE2T might promote the development and progression of NPC by activating the AKT/GSK3β/β-catenin pathway [210]. However, it remains challenging to develop effective molecules that specifically target this pathway to improve cancer therapy. We believe that maintaining the activity and expression level of related E2s in cancer cells might be a way to control cancer cell proliferation and metastasis.

4.5. Nuclear Factor-Kappa B (NF-κB) Pathway

E2s participate in signaling pathways by modifying certain key substrates, including mTORC1, PTEN-AKT, TNF, TLR, NLR, RLR, and TCR. In addition to acting through NF-κB, it also acts through interferon regulatory factors (This topic has recently been expertly reviewed [211]). The NF-κB signaling system (including the NF-κB dimer, IκB, and IKK) can respond to stimuli from a variety of signaling pathways such as TNF, TLR, NLR, RLR, and TCR [212]. Although NF-κB exists widely, it exists in an inactive state in most cells. This is because NF-κB is “trapped” by IκB in the cytoplasm of unstimulated cells [213]. The degradation of IκB, the key inhibitor of NF-κB, is coordinated by at least four post-translational modifications, allowing activation only when several prerequisites are met [165]. Under the action of various stimulating factors, including microorganisms, UBE2N and UBE2V1 form a heterodimer, which binds to the loop domain of TNF receptor associated factor (TRAF) family of adaptor proteins. This promotes the activation of TNFR and TLR protein kinases involved in signal transmission [214]. UBE2D1 can collaborate with c-IAP1 and mediate TNF-α stimulated receptor-interacting protein 1 (RIP1) ubiquitination [215]. UBE2N-UBE2V1, TRAF6, and TRAF2 are involved in the formation of Lys63-linked chain on NF-κB essential modifier (NEMO)/IKKγ and/or RIP1 [216,217,218,219]. After a series of reactions, IκB is phosphorylated and activated. After phosphorylated IκB enters the UPP, it forms a Lys48-linked ubiquitin chain under a two-step mechanism mediated by UBE2D and UBE2R1 [220]. Finally, IκB is rapidly degraded, releasing NF-κB into the nucleus, where it activates the transcription of a series of genes [221] (Figure 5). UBE2N-UBE2V1 not only mediates NF-κB activation, but also activates the RHBDF2-TACE signaling pathway to antagonize NF-κB activation. Thus, UBE2N-UBE2V1 plays dual roles in regulating the NF-κB pathway [222]. Besides, UBE2I also has a dual role in the regulation of NF-κB. SUMO1 acylates IκB and inhibits its ubiquitination, while SUMO2/3 plays the opposite role, that is, it promotes the ubiquitination and degradation of IκB [223]. The products of NF-κB target genes TNFAIP (TNF alpha induced protein 3, also known as A20) and IκBα terminate NF-κB activation.

Figure 5

E2s participate in the NF-κB pathway. (A) T cell receptor (TCR) stimulation promotes the binding of SLP-76 and UBE2I and increases the SUMOylation of SLP-76. SLP-76 and UBE2I synergize to augment TCR-mediated IL2 transcription by nuclear factor of activated T cells (NFAT) in a manner dependent on SUMOylation of SLP-76 [232]. (B) Under the action of the stimulation signal, IκBα will rapidly undergo phosphorylation modification under the stimulation of IKK. IKK contains two catalytic subunits, IKKα and IKKβ, and one regulatory subunit IKKγ [225]. In the classical pathway, IKKβ phosphorylates IκBα and is then recruited into the SKP1/CUL1/F-box protein (SCF) complex via βTrCP containing the F-box domain. βTrCP contains a WD40-repeat domain, which can specifically bind to two phosphorylated serine sites on the N-terminus of IκBα [233]. The RING domain contained in ROC1 can recruit E2 and to polyubiquitinylate phosphorylated IκBα, so that it is degraded by the 26S proteasome and “releases” NF-κB into the nucleus [234]. (C) In the non-classical pathway, activation of the pathway was suggested to depend on receptor-induced TRAF3 degradation and stabilization of NF-κB inducing kinase (NIK) [235]. TRAF3 physically associates with NIK via a specific sequence motif located in the N-region of NIK and ubiquitinates NIK to stabilize it with UBE2D [226]. CD40 and B cell activativing factor belonging to the TNF family (BAFF) of the tumor necrosis factor (TNFR) superfamily activate NIK selectively, and then NIK phosphorylates and activates IKKα. Activated IKKα catalyzes the phosphorylation of the two Ser sites at the C-terminus of the p100 precursor protein, and the phosphorylated modified p100 is recognized by the SCF-βTrCP complex [236]. The proteasome only degrades the C-terminus of p100 that contains ankyrin repeats, but does not affect the N-terminus (that is, the p52 subunit) containing the rel-homology domain (RHD) [237]. Then, p52 combines with RelB to form a dimer, which promotes the expression of target genes that can mature and activate B cells [238].

In normal cells, NF-κB becomes activated only after the appropriate stimuli, and then upregulates the transcription of its target genes [224]. In cancer cells, different types of molecular alterations might result in impaired regulation of NF-κB activation. In such case, NF-κB loses its inducibility and becomes constitutively activated [225]. This leads to deregulated expression of genes under NF-κB control. Although NF-κB is known to regulate immune and inflammatory responses, it also regulates the expression of cancer cell related genes such as those involved in proliferation (e.g., CCND1), angiogenesis (e.g., VEGF), invasion (e.g., MMP9), metastasis (e.g., ICAM1), and apoptosis (Promoting apoptosis (e.g., FAS) or Inhibiting apoptosis (e.g., BCL2)) [226]. UBE2V1 mRNA levels appeared to be elevated in all cancer cell lines examined [227]. Constitutive high-level expression of UBE2V1 alone in cultured human cells was sufficient to cause a significant increase in NF-κB activity, as well as the expression of its target anti-apoptotic protein, BCL2 [228]. Overexpression of UBE2V1 can inhibit stress-induced apoptosis of HepG2 cells by activating NF-κB signaling. Overexpression of UBE2V1 alone in BC cells was sufficient to activate NF-κB, which in turn upregulated the MMP1 expression to enhance BC cell metastasis [229]. Collectively, these observations establish a close correlation between UBE2V1 expression and tumorigenic potential. The N-terminal region of UBE2V1 is the molecular determinant of its cellular functions in the NF-κB signaling pathway. Therefore, an ideal inhibitor should target the N-terminal region of UBE2V1 instead of the UBE2N-UBE2V1 interface. RIP1 forms a Lys11-linked polyUb chain under the action of UBE2D, UBE2S, and c-IAP1. NEMO effectively binds to the Lys11-linked polyUb chain, which might play a signal role in the activation of cell proliferation pathways [230]. After NF-κB is activated, it can stimulate activated macrophages to release pro-inflammatory mediators and promote the growth of cancer cells [231]. These imply a tumor promotion function of E2.

4.6. Other Cases

The number of identified substrates conjugated by a particular Ub varies considerably, with tens of thousands of substrates identified for ubiquitin, thousands for SUMO, just a few for URM1, and two for ATG [32]. Therefore, there are many more E2s modified substrates that could participate in the regulation of cancer. For example, the UBE2N-UE2V1A complex and TRAF6 together trigger the Lys63 ubiquitination of AKT kinase. Then, AKT is phosphorylated to inhibit the regulation of BC cell cycle arrest and apoptosis by the FOXO1 transcription factor [239]. UBE2N activates non-SMAD signals through the TAK1-p38 MAP kinase cascade to regulate BC transfer, which is achieved by UBE2N activation of mitogen-activated protein/ERK kinase kinase 1 (MEKK1) and TAK1 [11]. UBE2T promoted the proliferation of renal cell carcinoma cells by regulating P13K/AKT signaling, suggesting that it might be a novel target for the treatment of patients with renal cell carcinoma [240]. UBE2N and UBE2D are required to initiate monoubiquitination and subsequent polyubiquitination of MHC class I molecules, which is necessary for their efficient endocytosis and endolysosomal degradation [241]. The UBE2D complex is critical to maintain KRAS protein stability, and targeting such a complex might be a unique strategy to degrade mutant KRAS to kill cancer cells [242]. Downregulation of UBE2O promoted AMPKα2-mediated suppression of the (mTORC1)-HIF-1α pathway, which is essential for metabolic “reprogramming” of cancer cells [243]. SUMOylated collapsin response mediator protein 2 (CRMP2) exists widely in GBM cells. Inhibition of CRMP2 SUMOylation could suppress GBM proliferation significantly in vitro [244].

Although cancers are derived from numerous tissues with multiple etiologies, and its progression carries with bewildering and seemingly endless combination of genetic and epigenetic alterations. However, there is a relatively small amount of “mission critical” events: deregulated cell proliferation and suppressed apoptosis. E2s not only promote the overexpression of these “mission critical” events in cancer cells, but also promote the progress of their entire life cycle. Understanding the biological processes involved and the related cancers are necessary for the initial selection of anti-cancer targets (Table 1).

Table 1

E2s, its synonyms, classification, relevant biological roles, and involvement in cancers.

Name(Human)	Synonyms	Classification	Biological Roles	Relevant Cancers
UBE2A	RAD6(A)	Class I	Transcriptional regulation	Chronic myeloid leukemia
			DNA repair [33]
			Regulating myeloid differentiation [34]
UBE2B	RAD6(B)	Class I	Ubiquitinating H2A/B and MGMT to participate in DNA repair	MM, BC
			Monoubiquitinating H2B to participate in transcriptional activation
UBE2C	UBCH10	Class II	Ubiquitinating p53 and Ki67 [35] to participate in G2/M transition [36]	MM of uterus, Melanoma, HCC [37], HNSCC [38], CRC [39], Glioma [40], TSCC [41], Cerebral cancer, LC, Leukemia, Lymphoma, GC [6,7,8,9], BC, Esophageal cancer, CC, Endometrial carcinoma, OC
			Regulating the level of phosphorylated ERK1/2 to participate in cell apoptosis [42]
			Its depletion reduced OC malignancy and reversed DDP resistance via downregulating CDK1 [43]
UBE2D(1/2/3)	UBCH5(a/b/c)	Class I	Regulating the level of p53 protein [44]	Esophageal cancer [45], PCa
			Ubiquitinating MDM2 and CCND1
UBE2E1	UBCH6	Class II	Affects the patient’s response to induction chemotherapy [46]	Acute myelogenous leukemia, PCa
UBE2E2	UBCH8	Class II	Stable substrate protein with ISG15 can promote cancer cell movement and invasion [47]	BC
UBE2E3	UBCH9	Class II	Maintaining mitochondrial homeostasis [48], participating in NEDD4− dependent epithelial Na+ channel regulation [49]	-
UBE2G1	UBE2G/E217K	Class I	Regulating inflammation and innate immune response [50], ubiquitinating and degrading of IKZF1 and IKZF3 [51]	Myeloma
UBE2G2	UBC7	Class I	Co-regulating immune receptor downregulation mediated by human cytomegalovirus US2 with TRC8 [52]	NSCLC [53], PCa [54]
UBE2H	UBC8/UBCH2	Class III	Participating in neurodevelopment [55]	-
			TNF-α promotes the binding of the UBE2H promoter region to NF-κB [56]
UBE2J1	UBC6	Class III	It negatively regulates interferon to promote RNA virus infection [57]	Medulloblastoma [58], PCa
			Participating in spermatogenesis and growth and development
UBE2J2	NCUBE2	Class III	Regulates ERAD induced by human cytomegalovirus US2 through TRC8 [52]	HCC [59]
UBE2K	UBCH1/E2-25k	Class III	Regulating the cell cycle	-
UBE2L3	UBCH7	Class I	Participating in DSB repair	HCC [60], Cervical Cancer [61], NSCLC [62], B-cell lymphoma
			Ubiquitinating p53 and p27Kip1 to regulate the cell cycle [63]
			Regulating the NF-κB signal driven by TNF-α [64], Rate limiting factors and therapeutic targets of LUBAC activity [65]
UBE2N	UBC13	Class I	UBE2N-UBE2V1 complex regulates innate immunity and participates in the activation of NF-κB [66]	BC, Cervical Cancer [67], HCC [68], DLBCL, LC, Malignant melanoma [69]
			UBE2N-UBE2V2 ubiquitinates PCNA and H2A
			Ubiquitinating and degrading Sirt1 and inhibiting histone H4 lysine 16 acetylation [70]
			Activating MAPKs
			Involved in the internalization of cell surface receptors
UBE2O	E2-230K	Class IV	Ubiquitinates BMAL1 to regulate transcriptional activity and circadian rhythm function [71]	BC [72], GC, RC [5], Anemia, MM, OC, HNSCC [73], LC [74]
			Participating in erythropoiesis, ubiquitinating RPs to participate terminal erythroid differentiation [75]
			Regulating apoptosis
			Monoubiquitinating SMAD6 to participate in bone morphogenesis [76]
			Ubiquitinating and degrading MXI1 at the Lys46 residue
UBE2Q1	UBE2Q/NICE5	Class II	Regulating p53 [77]	HCC, BC, ALL [78], CRC [79]
			Regulation of lysosome integrity and lysophagy [80]
UBE2Q2	Nothing	Class II	Regulating apoptosis	HNSCC [81], CRC [82]
UBE2R1	CDC34/UBC3/UBCH3	Class III	Ubiquitinating and degrading p27Kip1 [83] and IκBα	MM, HCC [84], NSCLC [85], ALL [86]
UBE2S	E2EPF/EPF5	Class III	Ubiquitinating CDKN1A, CCNB1, CDC20, and p53 (Lys11/Lys48 polyUb chain) to regulate apoptosis	HCC [68], BC, OSCC [87], NSCLC [88], Melanoma [89], CRC
			Ubiquitinating β-catenin to maintain its stability
			Ubiquitinating SOX2 to regulate neuroectodermal differentiation and maintaining mES cells [90]
UBE2T	FANCT/PIG50/	Class III	Nucleic acid excision repair for UV damage [91]	FA [65,92], GC [93], Osteosarcoma [94], PCa [95], LC [96], BC [97], HCC [98], Intrahepatic cholangiocarcinoma[99], Gallbladder cancer [100], NPC, CRC, MM [101], OC [102]
			Ubiquitinating and degrading p53 [101]
			Participating in Wnt/β-catenin signaling and P13K/AKT signaling, regulating BRCA1 degradation
UBE2V1	UEV1A	Class II	It participates in the activation of NF-κB together with UBE2N [71]	Metastatic CRC, BC, Osteosarcoma [103]
UBE2V2	MMS2	Class I	Participates in DNA repair together with UBE2N	-
UBE2W	UBC16	Class I	UBE2W downregulation promotes cell apoptosis and correlates with hypospermatogenesis [104]	-
BIRC6	Appolon/BRUCE	Class IV	A positive regulator of macroautophagy/autophagy [105]	HCC [106,107], NB [35,108], CRC, PCa [109], OC [35]
Ub-like
UBE2F	NCE2	Class II	Promoting the survival of lung cancer cells [110]	LC
UBE2I	UBC9	Class I	Promoting the development of T cells [111], SUMOylation of IRF4 promotes the M2 process of macrophages [112], SUMOylation of IRF7 limits its transcriptional activity [113]	HCC [114], BC
			SUMOylation of (SUMO1) NLRP3 activates the inflammasome, Regulating the NF-κB signaling [115]
			Participating in the formation of Lys49 polyUb chain to resist senescence [116]
			Affects BCL2 expression through the ER signaling pathway [117]
			UBE2I-PCGF2 complex inhibits the SUMOylation of PML-RARA [118]
			Participating in the development and survival of CLPs [119]
UBE2M	UBC12/UBC-RS2	Class II	DNA repair [120]	HCC [121], RC [122], LC, Intrahepatic cholangiocarcinoma [123]
			Ubiquitinating and degrading UBE2F [124]
			Participating in the cell cycle [125]
UBE2Z	USE1/HOYS7	Class IV	Participating in the ERK and STAT3 signal pathway [126]	HCC

5. Inhibitors and miRNAs Targeting E2s

Cancer cells’ rapid division and disordered regulatory pathways make them more susceptible to proteasome inhibition; therefore, proteasome inhibitors have become a new class of chemotherapeutic drugs that cause cell cycle arrest and cell death. We know that the UPP is currently one of the most widely studied target in disease treatment. Velcade and Krypolis, which inhibit the activity of the 26S proteasome, have been developed successfully to treat a variety of blood diseases [245]. The proteasome is the last step of the ubiquitination process and targets large amounts of ubiquitinated proteins for degradation; therefore, inhibiting the proteasome might lead to the accumulation of upstream ubiquitinated proteins. This could have serious consequences, which limit the widespread use of these drugs. Therefore, we could turn our attention to the specific components in the UPP, which might be a better strategy to specifically suppress them. Currently, inhibitors targeting E3 ligases and DUBs have been used in clinical trials to treat cancer [246]. Inhibitors targeting E2s are still in basic research, such as preliminary screening. There are few E1s; therefore, targeting E1s might affect multiple ubiquitination pathways. Based on the central position of E2s in the UPP and their appropriate quantity and special structure, one or more of E2s could be considered as targets to develop anticancer drugs, so as to provide the specificity that E1 inhibitors cannot achieve.

Most of the E2 inhibitors currently studied change activity of E2s by binding to the active site, allosteric site, or protein interaction site (Table 2). UBE2I is an anti-cancer target for cancers driven by MYC and RAS/RAF. Researchers used the X-ray crystal fragment screening method to find an allosteric small molecule binding site on the back of UBE2I. They believe that compounds that bind to this site might interfere with various protein-protein interactions in UBE2I’s activities [247]. It was reported that arsenic can cross-link adjacent cysteines in the catalytic domain of UBE2O, which can be used as a method to inhibit UBE2O activity. Arsenic is currently in clinical trials for various cancers [30]. The ligand molecules of the UBE2D2 activate site obtained through virtual screening include pyridine, piperidine, and azol ring scaffolds, which can be used as candidates for the development of anticancer drugs [248].

Table 2

Inhibitors and miRNAs targeting E2s.

Name	Target	Origin	Inhibition Mechanisms	Test Diseases	Characteristics
Inhibitors
IJ-5 [249]	UBE2D3	Herb	Combines with Cys85 of UBE2D3 to inhibit NF-κB signaling	Arthritis, Hepatitis	Difficulty in synthesis
Compound 6d [250]	UBE2D3	α-Santonin derivatives	Same as above	Arthritis	The efficacy of 6d is greater than IJ-5, but 6d is unstable
1β-hydroxy alantolactone [251]	UBE2D	Herbal medicine	Same as above	Inflammation	It is more efficient in combination with UBE2D3
CW3 [252]	UBE2G2	Synthesis	The vinyl group of CW3 inhibits E2 by forming a covalent bond with the thiol group of Cys48 of UBE2G2	Melanoma	-
TZ9 [253]	UBE2B	Synthesis	-	BC	Selective suppression
New triazine drugs (6a-c) [151]	UBE2B	Based on TZ9 synthesis	It incorporates deep inside the UBE2B binding pocket by interaction with UBE2B active site residues Cys88 and Asp90.	OC, LC, BC, CC	Inhibitory activity > TZ9, Selective suppression
CC0651 [254]	UBE2R1	Synthesis	It inserts into the hidden binding pocket of the non-catalytic site of UBE2R1 and interferes with the release of Ub to the Lys residue of the substrate	-	Allosteric inhibition
2-D08 [255]	UBE2I	Synthesis	Preventing transfer of SUMO from the UBE2I-SUMO thioester to the substrate	-	In vitro biochemical test
Compound 2 [256]	UBE2I	Synthesis	Binding near the active site of UBE2I	-	Low potency, low selectivity
Leucettamol A [257]	UBE2N	Leucetta aff. microrhaphis	Inhibiting the formation of the UBE2N-UBE2V1 complex	-	Its hydrogenation increased its inhibitory activity
Manadosterols A and B [258]	UBE2N	Lissodendoryx fibrosa manadosterols	Same as above	-	The activities are more potent than those of Leucettamol A
NSC697923 [259]	UBE2N	Synthesis	Impeding the formation of the UBE2N and Ub thioester conjugate.	NB	Efficacy > Doxorubicin and Etoposide
Luteolin and Quercetin [260]	UBE2S	Plants	-	Cervical cancer	-
CU2 [261]	UBE2T	Synthesis	Inhibiting UBE2T/FANCL-mediated FANCD2 monoubiquitylation	-	Cell and biochemical tests
miRNAs
miR-548e-5p [262]	UBE2C	Human LC organization	Binding to the 3′-UTR of UBE2C	NSCLC	In vitro test
miR661-3p [263]	UBE2C	Human 293 cells	Binding to the 3′-UTR of UBE2C	NSCLC	In vivo and in vitro tests
miR-381-3p [264]	UBE2C	Human PCa cells	ICT upregulates the level of miR-381-3p to downregulate the expression of UBE2C in human PCa cells	PCa	In vivo and in vitro tests
miR-147b [69]	UBE2N	HC organization	Binding to 3′-UTR of UBE2N	HC	In vivo and in vitro tests
miR-1305 [265]	UBE2T	Synthesis	Binding to 3′-UTR of UBE2T	LC	In vivo and in vitro tests
miR-214 [266]	UBE2I	Synthesis	Binding to 3′-UTR of UBE2I	Glioma	In vitro test

In addition to directly targeting the structure of E2s using small molecule inhibitors, the use of miRNAs to inhibit E2 mRNAs might also affect the protein turnover process of cancer cells. miRNAs are endogenous small noncoding RNAs that participate in the regulation of gene expression [267]. miRNAs, as natural antisense nucleotides, showed reduced immune response and low toxicity compared with plasmid DNA-based gene therapy and protein-based drug molecules [268]. However, the low stability of miRNAs and their difficult delivery into cells restrict their application in clinical practice. The delivery of miRNAs combined into nanostructures might improve their biodistribution and accumulation at the target site, with some papers showing encouraging results, both in in vitro and in vivo [269]. miRNA drugs can target molecules that cannot be targeted by chemical drugs or antibody drugs, and are expected to make breakthroughs in cancers with poor efficacy under traditional drugs treatment. Table 2 summarizes the miRNAs that target E2 members, providing a reference for the development of miRNA anticancer drugs.

6. Concluding Remarks and Future Perspectives

Through this review, we can see that E2s participate in different biological processes by modifying different molecules, and their abnormal activation or dysfunction might lead to the occurrence and development of cancer. Targeting certain E2 alone might affect a variety of biological processes. For example, the inhibition of UBE2N might affect the NF-κB pathway involving UBE2V1 and the DNA repair pathway involving UBE2V2. IJ-5 exerts an anti-inflammatory effect by binding to the active cysteine site of UBE2D; however, enzymes such as DUBs, other cysteine proteases, and protein tyrosine phosphatases also have cysteine active sites. Thus, IJ-5 might also inactivate these enzymes.

Based on a wide range of substrates and functions that are affected by E2s, it is necessary to use appropriate in vivo models and genetic methods to study the unique mode of action, functions, and specific modifications performed by a single E2 in different biological environments. Finally, new treatment options will be studied for a single E2, E2 complex, or specific E2-E3 interaction. In addition, it is necessary to understand the relationship between the principle of a drug’s action and the pathogenesis of the treated disease, and to develop the best drugs for comprehensive clinical evaluation. The development of drugs is not done overnight. Although some compounds that inhibit E2s are summarized in Table 2, they are limited to experimental studies. Therefore, the development of E2 inhibitors for clinical treatment remains challenging. Specific modifications to the reported E2 inhibitors to reduce these shortcomings, optimize their efficacy, and their use in combined applications (chemotherapy drugs and inhibitors or multi-target inhibitors), might achieve unexpected results.

This article clarifies the molecular basis of E2s as a cancer treatment target and the efforts made to develop E2 inhibitors based on the special position and role of E2s in the UPP, the structure of E2s, and the biological processes that E2s participate in. Currently, no E2 inhibitor is actually used in the clinical treatment of cancer; however, its potential as a therapeutic target cannot be ignored. In addition, this review also provides a deeper understanding of the various roles played by E2s in cells and the impact it produces, which could provide a reference for basic research into E2s.