Most BC cases (~70%) are luminal type and thus are ERα+. ERα is a nuclear receptor activated by estrogens. It is also activated via phosphorylation induced by growth factors such as insulin-like growth factor (IGF) and epidermal growth factor (EGF) in BC cells [32, 33, 35, 36]. Although ERα is a nuclear receptor, it is also associated with cytoplasmic proteins and transmembrane receptors. ERα can also be membrane-associated via its palmitoylation [37, 38]. Extranuclear ERα is part of the signaling route that may lead to gene regulation [39–41]. Nuclear ERα can act as a transcription factor or a coregulator that modulates gene expression [42, 43]. Estradiol, the most abundant estrogen, induces the expression of its target genes through ERα activation. Many of those target genes are associated with pro-tumor activity in BC cells (Figure 2) [44, 45].

The structure of ERα, from the N-terminus and C-terminus, consists of the activation function domain-1 (AF-1), the DNA-binding domain (DBD), a hinge region, the ligand-binding domain (LBD), and the activation function domain-2 (AF-2) [46, 47]. AF-2 recruits coregulators in an estradiol-dependent manner. AF-1 does the same in an estradiol-independent manner. AF-1 (in residues that include S118 and S167) is a target of phosphorylation by EGF and IGF signaling, activating the action of the receptor [44, 48–51]. The expression and recruitment of coactivators for ERα are usually increased in BC, enhancing the expression of their target genes [30, 45, 52–54]. Through DBD, ERα binds to EREs contained in the enhancers and promoters of their target genes to modulate its expression. Moreover, forkhead box A1 (FOXA1) and GATA binding protein 3 (GATA3) are considered pioneer factors that facilitate the recruitment of ERα to ERE in DNA regulatory sequences [55, 56].

Approximately 20% of all BCs are HER2+ [57]. HER2 is a member of the EGF receptor family and is also known as the proto-oncogene neu and ErbB2. HER2+ BC cases are characterized as being highly aggressive, recurrent, and having a poor prognosis. Nearly 50% of these cancer cases also display co-expression with hormone receptors [58, 59]. The gene that encodes HER2 is on chromosome 17q12 and is known as ErbB2 receptor tyrosine kinase 2 (ERBB2) [60, 61]. HER2 is a transmembrane receptor with tyrosine-protein kinase activity, but it does not have the ability to recognize growth factors nor can it be activated by growth factor ligands directly, as it lacks the ligand-binding extracellular domain [60, 62, 63]. HER2 associates with other members of the EGF receptor family that do possess the ligand-binding ability, forming heterodimers that trigger downstream signaling, such as phosphatidylinositol-3 kinase and MAPK activation, promoting BC progression [60, 62].

Endocrine therapies (ET) are used for ERα+ BC cases because they enclose aromatase inhibitors (AIs) and selective estrogen receptor modulators (SERMs). AIs block estradiol production, whereas SERMs are a type of ET that acts by competing with estradiol by binding to ERα and inhibiting the recruitment of coactivators. SERMs promote the interaction with corepressors to avoid the transcription of estradiol-target genes in BC cells [64–66]. A common problem of these types of ET is de novo resistance and acquired resistance [65–69]. The mechanisms underlying the resistance to ET are not completely understood, but they have been shown to be related to signaling pathways activated by ERα [69, 70].

Interestingly, mutations in estrogen receptor 1 (ESR1), the gene that encodes ERα, specifically the mutations Y537S, Y537N, Y537C, D538G, and E380Q, have been found in circulating tumor DNA and biopsies of metastatic BC with resistance to ET [71–73]. These mutations encompass the LBD and allow ERα to act in an estradiol-independent manner, modifying the profile of ERα target genes, some of them associated with endocrine resistance to ET [72, 74–77].

Selective estrogen receptor degraders (SERDs) are another ET that are considered as antiestrogens and antagonize estradiol [66–68]. However, the binding of SERDs to ERα promotes the polyubiquitination and degradation of this receptor through the UPS [64, 78, 79]. To date, fulvestrant is the most important SERD described since even the commonly reported ESR1 mutations seem to be sensitive to this SERD [72, 75, 76]. Although several SERDs are being evaluated, fulvestrant is the first SERD approved as a first-line ET to date [80]. It is hoped that the new generation of SERDs will have improved bio-dispensability and administration routes in comparison with fulvestrant, which is administrated intramuscularly and has a limited bio-dispensability [81–86].

The mechanism of SERDs is based on ERα degradation via the UPS, which has significant advantages compared to the mechanisms of SERMs. New therapeutic strategies that are also based on ERα polyubiquitination as a marker for its degradation via the UPS are PROTACs (Figure 2C), as will be discussed in the latter half of this review.

An improvement in the prognosis of HER2+ BC has been observed as a result of different therapeutic strategies. The first approved therapy for HER2+ BC was adjuvant chemotherapy called trastuzumab, which consists of a humanized monoclonal Ab that specifically recognizes HER2, inhibiting HER2 dimerization [87]. Other HER2-directed monoclonal antibodies, such as pertuzumab, have now been generated. Additionally, novel strategies have emerged, including Ab-drug conjugates (ADCs) and tyrosine kinase inhibitors (TKIs) [88].

ADCs are recombinant monoclonal antibodies covalently bonded to a cytotoxin, generating a chemotherapeutic drug specifically targeted against HER2. This allows for intracellular delivery of the cytotoxic drug [89]. The bonds between the monoclonal Ab and cytotoxic drug are cleaved once the Ab binds to its target antigen, allowing the cytotoxic drug for use on other cells [89, 90]. Trastuzumab emtansine (T-DM1) is a non-cleavable ADC, showing antitumor activity in HER2+ BC [91]. Despite its therapeutic effects, since HER2 can be expressed in other cells and since cytotoxic drugs can be internalized in cells with low HER2 expression, gastrointestinal, hematologic, and hepatic toxicity has been reported. Therefore, further investigations are required to ensure the safe use of the ADCs in BC [92, 93].

TKIs, such as lapatinib, neratinib, tucatinib, and pyrotinib, are also used to treat HER2+ BC. TKIs can be used in combination with chemotherapy [88]. TKIs are of interest for the treatment of HER2+ cells that are resistant to the other therapies. The resistance to therapies has been associated with HER2 reactivation, HER2-dependent downstream signaling, upregulation of the HER receptor family, and HER2 mutations [94–97]. For example, L755S is an acquired activating mutation of HER2 identified in HER2+ metastatic BC, which may prevent the binding of the monoclonal antibodies and lapatinib activity [94, 95, 98]. With the use of TKIs as a BC treatment even with HER2 mutations, there is an increasing interest in developing novel TKIs for HER2+ BC [94, 96].

PROTAC-2, PROTAC-B, compound 24, compound 11, and estrogen receptor degrader (ERD)-148, among other PROTACs, have been designed to induce the reduction of ERα levels in BC cells (Figure 3) [99–101]. PROTAC-2 was designed with an estradiol molecule to bind to ERα and the phosphopeptide of IκBα that recruits SCF^β-trcp Ub ligase complex, leading to ERα degradation [102]. PROTAC-B displays a peptide from hypoxia-inducible factor-1α (HIF-1α) that allows for the recruitment of the E3-Ub ligase VHL [103, 104]. E2-octa and E2-penta contain synthetic peptides derived from HIF-1α, resulting in an efficient reduction of ERα levels [101]. Additionally, specific and non-genetic IAP-dependent protein eraser (SNIPER) is a PROTAC formed by a derivative of estradiol along with a bestatin amide that binds the cellular inhibitor of apoptosis protein 1 (cIAP1) ligand which induces ERα degradation [23, 105, 106].

Another example is compound 1–6, which was designed as a peptide-based PROTAC with better penetration [26]. Similarly, TD-PROTAC is another peptide-based PROTAC constructed from TD-PERM (a stabilized peptide that binds to ERα), the linker, and the hydroxyproline-containing pentapeptide from HIF-1α to recruit the VHL E3 Ub ligase complex. TD-PERM promotes 75% reduction in tumor volume in michigan cancer foundation-7 (MCF-7) mouse xenograft model [99].

Furthermore, ERD-308 PROTAC induces ERα degradation by reducing cell proliferation to a greater extent than fulvestrant (> 95% of ERa degradation at concentrations as low as 5 nmol/L in MCF-7 and T47D BC cells) [25]. ARV-471 PROTAC reduces ERα levels and its Y537S and D538G variants. Furthermore, ARV-471 significantly reduces estradiol-dependent MCF-7 xenograft tumors and tumor ER protein levels (> 90%) [27, 107]. Other PROTACs have also been evaluated in vitro as well as using in vivo models, and indicated a reduction in cell proliferation, inhibition of estradiol target genes, and induction of apoptosis in both models. This suggests that PROTACs have a strong antitumor therapeutic effect [99]. However, ARV-471 has been proposed as the best-in-class oral ERa PROTAC due to its results in preclinical trials. Currently, ARV-471 is in phase 2 studies to treat advanced or metastatic ER+/HER2+ BC [107, 108].

New PROTAC designs consider the use of monoclonal antibodies to target specific proteins. For example, a study generated a new PROTAC with Ab linker named Ab-PROTAC3, a trastuzumab-PROTAC conjugate. This conjugate has the ability of PROTACs to recruit E3-Ub ligase specifically to HER2+ cells through trastuzumab. Then, trastuzumab-PROTAC can be internalized into the cell, and active PROTAC is released to promote the degradation of bromodomain-containing protein 4 (BRD4) [109].

PROTACs can be applied to other proteins implicated in the progression of BC. For example, B-cell lymphoma-extra large (Bcl-xL) is overexpressed in several cancer types, including BC. The PROTAC named 8a can promote the Bcl-xL degradation in BC cells [110]. Additionally, the bromo and extra terminal domain proteins (BET) such as BRD2, BRD3, and BRD4 are epigenetic regulators considered potential targets for BC treatment. It has been generated PROTACs for BRD4 using VHL E3 ligase and for BRD2, BRD3, and BRD4, using E3 Ub ligase cereblon (CRBN), showing results in triple-negative BC [111, 112]. Thus, several proteins involved in BC may be targeted by PROTACs.