The p53 is a tumor suppressor encoded by TP53 that facilitates cell cycle control, DNA repair and apoptosis in response to various cellular stresses, thereby quenching the growth and proliferation of abnormal cells (92, 93). Genetic inactivation of p53 enable mutant tumor cells to circumvent these checkpoints (94). Indeed, p53 deficiency in association with activating mutations of oncogenes, such as RAS and BRAF, accounts for the high proliferation rate and increased aggressiveness of the more aggressive forms of thyroid cancer (95).

TERT is important for maintaining chromosomal integrity and genome stability (96). In most somatic cells, telomeres shorten with cell division, and when their length reaches a critical point, cells enter senescence or apoptosis (96).However, in thyroid cancer cells, an activating mutation in the TERT promoter (TERTp) prevents telomere shortening, allowing tumor cells to continue dividing and proliferating (97), thereby driving disease progression. The common TERTp mutations in thyroid cancer are two mutually exclusive mutations, C228T and C250T (98). These mutations form a consensus binding site for the E-twenty-six (ETS) transcription factor in the TERTp region, increasing its transcriptional activity (98). TERTp mutations, as a late event in tumor progression (55, 98), can also occur simultaneously with BRAF or RAS mutations in poorly differentiated and anaplastic thyroid cancers (99, 100), enhancing tumor aggressiveness (100–105). Therefore, they can be served as an early predictor of RAI-RTCs (106). Recently, some mouse model studies have shown that TERT reactivation can accelerate progression of BRAF-driven thyroid tumors via non-telomeric effects such as cytokine and PI3K signaling (107, 108). This association of TERT and PI3K signaling pathway may shed some light on the role of TERT in the pathogenesis of thyroid cancer as well as RAI-RTCs.

The function of SWI-SNF complexes is to reconfigure chromatin, thereby determining the expression of certain genetic programs. Dysfunction of SWI-SNF can induce stem cell-likeness (109). Genetic alterations disrupt genes that encode members of the SWI-SNF chromatin remodeling complex (for example, ARID1A, ARID1B, ARID2, SMARCB1 or PBRM1) occur in 6% of PDTCs and 36% of ATCs (55). Among those, thyroid cancers with BRAFV600E and SWI-SNF impairment were locked in a dedifferentiated transcriptional state that could not be reversed by MAPK signaling pathway inhibition (110), which would discourage the use of redifferentiation strategies.

Changes in the WNT/β-catenin signaling pathway (111), histone deacetylase (HDAC) isoforms (112), aberrant gene methylation (113, 114), peroxisome proliferator activated receptor gamma (PPAR-γ) rearrangement with PAX8 ( 115), and imbalance of ncRNAs (116) have also been observed in RAI-RTCs and take part in its occurrence and development.

In addition to VEGFR, PDGFR, FGFR, RET and c-KIT, which all belong to RTKs, the targets of MKIs also include BRAF and RAS. Representative drugs include sorafenib, lenvatinib, motesanib, pazopanib and sunitinib, among which sorafenib and lenvatinib have been approved by the US FDA for the clinical treatment of RAI-RTCs. The other drugs have been shown to be effective in preliminary clinical trials, yet have not been approved to include RAI-RTCs in their indications for their lack of multicenter large-sample trial data.

Sorafenib was originally developed by Bayer (Leverkusen, Germany), and its main targets are VEGFR 1-3, RET, RAF (including BRAF and C-Raf), PDGFR-β, c-KIT and FLT3 (121). In an earlier phase II single-arm clinical trial that included 31 patients with advanced RAI-RTCs, the median progression-free survival (PFS) after treatment was 18 months, and the median overall survival (OS) was 34.5 months (122). More reliable data were obtained in a multicenter, double-blinded, randomized controlled phase III clinical trial (DECISION; ClinicalTrials.gov number, NCT00984282) in 2012, with 417 patients included. The median PFS was significantly increased in the sorafenib group (n=207) compared with that in the placebo group (n=209) (10.8 months vs. 5.8 months) (123). Therefore, sorafenib was approved by the US FDA and the European Medicines Agency in November 2013 for the treatment of advanced RAI-RTCs with a recommended starting dose of 800 mg/day in divided doses. The common adverse effects are palm-plantar swelling, diarrhea, hair loss, rash and scaling, which primarily occur during the first 6 cycles of treatment and may gradually get tolerated as the course of treatment prolongs. However, these adverse events resulted in discontinuation of treatment in 66% of patients, dose reduction in 64% of patients, and permanent discontinuation in 18% of patients (124).

Lenvatinib targets VEGFR 1-3, FGFR 1-4, PDGFR-α, RET and c-KIT (125). Previous studies have suggested that its antitumor effect is mainly directed against the microvascular environment of VEGFR and FGFR rather than against tumor cell proliferation or a specific phase of the cell cycle (126, 127). The efficacy of lenvatinib has been demonstrated in a randomized, double-blinded, multicenter phase III clinical trial (SELECT; ClinicalTrials.gov number, NCT01321554). A total of 392 patients with advanced RAI-RTCs were recruited in this study, and the primary endpoint was PFS. The PFS of the lenvatinib group (n=261) and the placebo group (n=131) were 18.3 and 3.6 months, respectively. The treatment response rate of the Lenvatinib group was 64.8% and four patients had complete responses (CR), while that of the control group was only 1.5% and all responses were partial (128). The US FDA approved lenvatinib as the second drug, after sorafenib, for the treatment of advanced RAI-RTCs in 2015, with a recommended starting dose of 24 mg/day (129). The most common adverse reactions are hypertension, diarrhea, fatigue, nausea, loss of appetite and weight loss. Adverse reactions led to discontinuation in 82.4% of patients, dose reduction in 67.8% and permanent discontinuation in 14% (128). A study exploring the optimal dose of lenvatinib to treat RAI-RTCs has shown that the 24-week objective response rates (ORRs) of the lenvatinib were 57.3% in the 24 mg/day (n=75) group and 40.3% in the 18 mg/day (n=77) group, respectively, with the odds ratio (OR) being 0.5. As for the incidences of adverse reactions, treatment-emergent adverse events (TEAEs)≥3 in each group were 61.3% and 57.1%, respectively. Therefore, the starting dose of 24 mg/day is confirmed and recommended (130) ( Table 1 ).

Cabozantinib, an inhibitor of VEGFR, AXL, MET, and RET, is the second-line treatment option in advanced RAI-RTC patients. The latest results from COSMIC-311 (registration number NCT 03690388) indicated that cabozantinib benefits patients with RAI-RTC, regardless of prior lenvatinib or sorafenib treatments (131). COSMIC-311 is an international, randomized, double-blind trial in which patients with locally advanced or metastatic RAI-RTC that progressed during or following treatment with lenvatinib, sorafenib, or both were treated with either cabozantinib (n = 170) or placebo (n = 88). The median PFS with cabozantinib was 16.6, 5.8, and 7.6 months for those patients who received prior sorafenib only, prior lenvatinib only, or both, respectively, versus 3.2, 1.9, and 1.9 months with placebo; hazard ratios (HRs) 0.13, 0.28, and 0.27, respectively (132). Therefore, cabozantinib has been approved by FDA and Germany as a second-line treatment option in advanced RAI-RTC (133, 134).

Another MKI drug, motesanib, targets VEGFR 1-3, PDGFR, RET and c-KIT (135). In an open-label single-arm phase II clinical trial of 93 patients, 14% had a partial response (PR) and 35% had stable disease (SD) for more than 24 weeks (136). Vandetanib is shown efficacy in a randomized phase 2 trial in 145 patients with locally advanced or metastatic differentiated thyroid carcinoma (18). Patients who received vandetanib had longer PFS than did those who received placebo (HR 0·63, 60% CI 0·54-0·74; one-sided p=0·008): median PFS was 11·1 months (95% CI 7·7-14·0) for patients in the vandetanib group and 5·9 months (4·0-8·9) for patients in the placebo group. And vandetanib has been approved by the FDA for the treatment of advanced medullary thyroid carcinoma (137). A randomized double-blind phase III clinical trial of vandetanib efficacy in RAI-RTC patients is still ongoing (see Table 1 for details).

Other MKIs include pazopanib (138), sunitinib (139) and imatinib. Clinical trials, most of which are small sample, single-arm, open-label, single-center phase II studies, have shown that pazopanib (140, 141) and sunitinib (142, 143) have some efficacy in RAI-RTCs patients, which still needs further verification. As for imatinib, a small clinical trial investigating whether it can promote RAI reuptake in RAI-RTCs is ongoing (see Table 1 for details).

In summary, sorafenib and lenvatinib have been approved by the FDA for the treatment of RAI-RTCs with the dose reduction and treatment discontinuation due to adverse reactions worthy of attention yet. Cabozantinib can be used as a second-line treatment for RAI-RTC that has progressed after sorafenib and Lenvatinib. The other MKIs, such as pazopanib, motesanib and sunitinib, have shown certain clinical efficacy in RAI-RTCs but large sampled multicenter randomized controlled trials are still needed to confirm their efficacy. Off-label use of unapproved MKIs may also be considered if disease progression occurs despite treatment with sorafenib or lenvatinib (144).

There are many types of selective kinase inhibitors including RET inhibitors, BRAF inhibitors, MEK inhibitors, mTOR inhibitors, VEGFR-2 inhibitors and histone deacetylase inhibitors (HDACis). Their therapeutic effect in thyroid cancer, has been confirmed by a number of clinical studies. Notably, BRAF and MEK inhibitors have achieved a major breakthrough in the treatment of RAI-RTCs with the BRAF^V600E mutation, which can cause RAI reuptake in some RAI-RTC lesions carrying BRAF/RAS mutations, allowing response to RAI treatment (145).

Immune checkpoint inhibitors (ICIs) are a new type of antitumor drug which can achieve antitumor goal by blocking the binding of immune checkpoints to their ligands, thereby enhancing the activity of T cells. ICIs mainly include CTLA-4 inhibitors and PD-1/PD-L1 inhibitors, which mainly used in the treatment of melanoma, Hodgkin’s lymphoma and non-small cell lung cancer (NSCLC). But the use of ICIs in thyroid cancer is questioned. On one hand, a large number of immune cells infiltrate DTC tissues, and this is closely related to tumor prognosis (169–173). Tumor patients with high expression of programmed death 1 (PD-1) and programmed death ligand 1 (PD-L1) often have an increased risk of tumor recurrence and shortened disease-free survival (DFS) (174–177). These mechanisms suggest that ICIs should be effective in treating thyroid cancer. On the other hand, the expression of PD-L1 in thyroid cancer fluctuates greatly (6.1% to 82.5%) (178), which creates uncertainty about the efficacy of ICIs to thyroid cancer.

Currently, the clinical application of ICIs for the treatment of malignant tumors includes CTLA-4 inhibitors (ipilimumab), PD-1 inhibitors (pembrolizumab and nivolumab), and PD-L1 inhibitors (durvalumab and atezolizumab). A single-arm study of 22 patients with PD-L1-positive DTC preliminarily explored the efficacy of pembrolizumab to thyroid cancer. The results were two cases of PR (9%) and a median PFS of 7 months (179), suggesting little efficacy of ICIs. Six studies of ICIs combined with targeted therapy or chemoradiotherapy are now in progress and most of them are nondouble-blinded phase II clinical trials with small sample sizes (refer to 4.5, see Table 3 for details).

Chemotherapy is the use of the anticancer or cytotoxic properties of drugs to kill cancer cells. For most malignancies, cytotoxic chemotherapy is a well-documented treatment with good clinical outcomes. The US FDA approved in as early as 1974 doxorubicin for the treatment of DTC, but its clinical benefit is diminished by its toxicity and side effects (180). Therefore, ATA proposed in 2015 that systemic chemotherapy no longer be the standard treatment for RAI-RTCs and only be considered when other options, such as TKIs, are ineffective (3).

In addition to the monotherapies adopting the foregoing drugs, sequential therapy and combination therapy also showed certain effects.

The efficacy of sequential therapy was studied in a phase II clinical trial of vemurafenib. Fifty-one patients with BRAF^V600E -positive RAI-RTC were divided into two groups in this trial according to whether they had received VEGFR-targeted TKI treatment before, and both groups were treated with vemurafenib. The antitumor effect was better in patients who had never received TKI therapy (PR, 38.5% vs. 27%; 6-month SD, 35% vs. 27%) (157).

The efficacy of combination therapies has been widely appraised. A retrospective study found that mTOR inhibitor sirolimus combined with chemotherapy drug cyclophosphamide reached a 1-year PFS rate comparable to standard treatment (0.45% vs. 0.30%) in the treatment of RAI-RTCs (181). There is currently a phase II clinical trial in progress that is using the two drugs combination in 19 patients with RAI-RTC (see Table 2 for details). Temsirolimus, another mTOR inhibitor, in combination with MKI sorafenib achieved PR of 22% and SD of 58% in 36 RAI-RTC patients (182). The combination therapy of somatostatin analog pasireotide and mTOR inhibitor everolimus in the treatment of RAI-RTC was also studied in a phase II clinical trial (NCT01270321), since it was observed that somatostatin receptor (SSTR) 2 was highly expressed in thyroid cancer and activation of the SSTR1-5 inhibited the signal transduction of the PI3K signaling pathway (183). It has been completed, but the results have not been published yet (see Table 2 for details). Another type of combination therapy is BRAF inhibitor dabrafenib combined with MEK inhibitor trametinib for BRAF-mutated RAI-ATC. In a randomized phase-II open-Label multicenter trial of 53 patients with BRAF-mutated RAI-RTC, this combination therapy was not superior in efficacy compared to dabrafenib monotherapy, within the ORR was 48% versus 42% (184). A new study shown that this combination therapy is effective in BRAF-mutated DTC patients for restoring RAI uptake with PR observed 6 months after RAI administration in 38% of the patients (185). There are also four ongoing clinical trials of dabrafenib in combination with other selective kinase inhibitors (see Table 2 for details). And two other studies are underway to investigate the response rate of MKI lenvatinib combined with ICIs in patients with RAI-RTC and the reuptake of RAI by lenvatinib on RAI-RTC lesions (see Table 2 for details).