Currently, the search for new promising tools of immunotherapy continues. In this regard, microRNAs that influence immune checkpoint gene expression in tumor and T-cells. An important feature of miRNA is its ability to affect the expression of several genes simultaneously, which corresponds to the trend toward the use of combination therapy.
Immunotherapy is an innovative method of cancer treatment. As a result of experiments and clinical trials, it has been found that immunotherapy can increase progressionfree survival and overall survival. However, this method of treatment is effective in a limited number of patients, and in addition, it can cause severe adverse reactions due to hyperreactivity of the immune system [1]. In this regard, research is underway to develop new therapeutic approaches based on targeting immune checkpoints (ICs). Tumor cells have the ability to generate ligands that can bind to co-inhibitory receptor molecules. This interaction suppresses the antitumor immune response, allowing the tumor to “escape” from the immune system. In order to increase the effectiveness of immunotherapy, the FDA approved a number of regimens, including a combination of two IC inhibitors, a combination of IC inhibitors and targeted therapy drugs, as well as antitumor bispecific antibodies [4,5]. It has been shown that in combination therapy regimens, patients experienced a higher response rate compared to monotherapy [6]. In addition, the search for a more promising immunotherapy approach is currently ongoing. In this regard, microRNAs (miRNAs) are considered. According to recent studies, miRNAs influence IC gene expression and are important regulators in both T-cells and tumor cells [7]. MiRNAs regulate gene expression by binding to the 3’-UTR of their mRNA [8–10]. MiRNAs can also affect IC expression indirectly, through molecules of different signaling pathways, such as PTEN, IFR-1, and others [11]. It is also important that one miRNA can affect several genes [7,12]. This article presents a review of miRNAs that interact with IC genes, analyzes their regulating IC expression in tumors of various types of cancer, and identifies miRNAs that act on several IC genes simultaneously. Due to these properties, miRNA-based therapy may become an alternative to the combination of targeted drugs in the future. In addition, miRNAs are considered that are capable of simultaneously regulating the expression of targeted therapy genes along with IC genes. These issues have not been previously analyzed in existing reviews of miRNAs as IC regulators [13–17]. We have reviewed more than 200 miRNAs that regulate ICs in tumors of various types.
Table 1. The miRNAs interacting with IC genes in different types of cancer
Immunecheckpoint |
microRNA |
Cancer |
Reference |
PD-1 |
miR-374b, miR-4717 |
Liver cancer |
[64,65] |
PD-1/PD-L1 |
miR-183 |
RCC |
[66] |
miR-138-5p, miR-200b, miR-429, miR-508 |
Lung cancer |
[67,68] |
|
PD-L1 |
miR-142-5p |
PC, OC |
[69,70] |
miR-497-5p |
ccRCC |
[71] |
|
miR-20-b, miR-21, miR-130b, miR-138-5p, miR-148a-3p, miR-191-5p |
CRC |
[11,72–74] |
|
miR-195, miR-424-5p, miR-497, miR-873, miR-3609 |
BC |
[75–78] |
|
miR-17-5p, miR-146a |
Melanoma |
[79,80] |
|
miR-15a, miR-15b, miR-16, miR-193a-3p, miR-320a |
Pleural Mesothelioma |
[81,82] |
|
miR-155, miR-195, miR-214 |
B-cell lymphoma |
[83–85] |
|
miR-16, miR-195 |
Prostate cancer |
[86] |
|
miR-34a, miR-34b, miR-34c, miR-140, miR-200, miR-200a-3p, miR-3127-5p |
Lung cancer |
[87–91] |
|
miR-34a |
AML |
[92] |
|
miR-23a-3p, miR-570 |
Liver cancer |
[93,94] |
|
miR-375 |
HNSCC |
[95] |
|
miR-145 |
OC, bladder cancer |
[96,97] |
|
miR-513a-5p |
Retinoblastoma |
[98] |
|
miR-105-5p, miR-152, miR-200b, miR-200c, miR-570 |
GC |
[99–103] |
|
miR-18a, miR-140, miR-142, miR-340, miR-383 |
Cervical cancer |
[104] |
|
miR-217 |
Laryngeal cancer |
[105] |
|
miR-20b-5p |
Models of lung and BC |
[106] |
|
miR-194-5p |
PC |
[107] |
|
PD-L1+B7-H3 |
miR-326 |
Lung cancer |
[8] |
PD-1, CTLA-4 |
miR-424 |
OC |
[108] |
miR-138-5p |
Glioma |
[109] |
|
CD80/CTLA-4 |
miR-424 |
CRC |
[110] |
PD-1, PD-L1, CTLA-4 |
miR-33a |
Lung cancer |
[111] |
PD-1, BTLA, Tim-3 |
miR-28 |
Melanoma mouse model |
[112] |
BTLA |
miR-32 |
OC |
[113] |
Tim-3 |
miR-498 |
AML |
[114] |
IDO1 |
miR-153, miR-448 |
CRC |
[115,116] |
Gal-3 |
miR-424-3p |
OC |
[117] |
miR-128 |
CRC |
[118] |
|
Gal-9 |
miR-22 |
Liver cancer |
[119] |
miR-15b-5p, miR-455-5p, miR-1237, miR-1246 |
CRC |
[120,121] |
|
ICOS (B7-H2)/ICOSL |
miR-24 |
GC |
[122] |
B7-H3 |
miR-29 (a, b, c) |
Neuroblastoma, sarcoma, brain tumors |
[123] |
miR-145 |
Lung cancer |
[124] |
|
miR-28-5p, miR-29a, miR-128, miR-145, miR-155/miR-143, miR-187, miR-192, miR-335-5p, miR-378, miR-1301-3p |
CRC |
[125–129] |
|
miR-187 |
ccRCC |
[130] |
|
miR-29c |
Melanoma,CRC |
[131,132] |
|
miR-29c, miR-34b, miR-124a, miR-125b-2, miR-214, miR-297, miR-326, miR-363, miR-380-5p, miR-506, miR-555, miR-567, miR-593, miR-601, miR-665, miR-708, miR-885-3p, miR-940 |
BC |
[133] |
|
miR-539 |
Glioma |
[134] |
|
miR-124 |
Osteosarcoma |
[135] |
|
miR-506 |
Mantle cell lymphoma |
[136] |
|
miR-214 |
Multiple myeloma |
[137] |
|
miR-29, miR-1253 |
Medulloblastoma |
[138,139] |
|
miR-199a |
Cervical cancer |
[140] |
|
B7-H5 (VISTA, BTNL2) |
miR-125a-5p |
GC |
[141] |
B7-H4 (VTCN1) |
miR-155/miR-143, miR-1207 |
CRC |
[126,142] |
miR-7–5p, hsa-let-7c, hsa-let-7f-5p, miR-17–3p, miR-21–3p, miR-21–5p, miR-24–1-5p, miR-27b-3p, miR-31–3p, miR-31–5p, miR-33a-5p, miR-33b-5p, miR-122–3p, miR-130b-3p, miR-138–1-3p, miR-148a-3p, miR-149–3p, miR-183–3p, miR-186–5p, miR-196a-5p, hsa-miR-204–3p, miR-299–5p, miR-302a-3p, miR-302e, miR-335–3p, miR-335–5p, miR-361–5p, miR-374c-5p, miR-483–3p, miR-513a-5p, miR-519e-3p, miR-520d-5p, miR-525–5p, miR-615–3p, miR-642a-5p, miR-744–5p, miR-937, miR-1246, miRPlus-G1246–3p, miR-1260a, miR-1265, miR-1284, miR-1290, miR-1973, miR-2115–3p, miR-2116–5p, miR-3178, miR-3202, miR-3646, miR-3651, miR-3676–3p, miR-3685, miR-3686, miR-4258, miR-4279, miR-4284, miR-4288, miR-4290, miR-4306, miR-4324 |
PC |
[143] |
|
B7-H6 (NCR3LG1) |
miR-93, miR-195, miR-340 |
BC |
[76] |
B7-H7 (HHLA2) |
miR-3116, miR-6870-5p |
ccRCC |
[144] |
The results of accumulated data analysis demonstrate a significant relationship between the action of miRNAs on ICs genes and the type of tumor—only about 14% (95% CI: 9.8–20.1%) of the studied miRNAs regulate the expression of specific IC in more than one type of cancer.
Currently, there are numerous studies underway to identify miRNAs that are the most promising as immunotherapy agents. In vivo experiments have repeatedly shown that miRNA-based therapy leads to significant tumor regression. Although miRNA has not yet entered the arsenal of antitumor agents used in practice, some results are encouraging. Thus, the miR-155 inhibitor has performed well in clinical trials. The study of miR-138 is promising. Ongoing research on miR-34a may also lead to a positive result. Thus, there is the prospect of using miRNA as a therapeutic agent in cancer immunotherapy regimens. At the same time, the ability of miRNAs to inhibit several genes can lead to adverse events. To overcome this, it is important to expand data of the spectrum of miRNA targets in a particular type of cancer. Additional studies of the miRNA–genes interaction features and the search for an optimal miRNA mimic structure are necessary, thus allowing an increase in the efficiency and selectivity of interaction with the mRNA of target genes. It can increase the effectiveness of therapy, as well as reduce the dose of the drug, thereby reducing its side effects.
This entry is adapted from the peer-reviewed paper 10.3390/ijms23169324