The Possible Role of the Long Non-coding RNA NORAD in Mitomycin C-Related Chemoresistance

İbrahim BOZGEYİK

doi:10.4274/nkmj.galenos.2022.70298

ABSTRACT

Aim:

Non-coding ribonucleic acid (RNA) activated by deoxyribonucleic acid (DNA) damage (NORAD) is a long non-coding RNA activated during DNA damage response. Accumulating evidence suggest that NORAD is overexpressed in human cancers and associated with the drug-induced chemoresistance. The present study aims to explore the possible role of long non-coding RNA NORAD during mitomycin C-related chemoresistance and mitomycin C-induced DNA damage response.

Materials and Methods:

In cell culture experiments, MDA-MB-231 breast cancer cells were used. MTT cell viability assay was used to determine the effects of mitomycin C on breast cancer cells and application dose was determined accordingly. For analysis of NORAD gene expression levels, quantitative real-time polymerase chain reaction method was used.

Results:

Mitomycin C was found to suppress cell viability of breast cancer cells in a dose-dependent manner and half-maximal inhibitory concentration was determined as 1.12 µg/mL (p<0.0001). Notably, significant differential activation of NORAD was determined in breast cancer cells treated with the mitomycin C (p<0.0001).

Conclusion:

Findings obtained here strongly suggest that NORAD is possibly involved in mitomycin C-related chemoresistance and mitomycin C-induced DNA damage response.

Keywords:

DNA damage, breast cancer, mitomycin C, lncRNA, NORAD

INTRODUCTION

Although the human genome harbors hundreds of long non-coding ribonucleic acid (RNAs) (lncRNAs), only about a dozen with distinct biological activities and biochemical processes have been identified. Non-coding RNA activated by deoxyribonucleic acid (DNA) damage (NORAD, formerly known as LINC00657), a particular lncRNA transcript which is stimulated in response to DNA injury, has been reported to be necessary for the maintenance of genome integrity¹. Deletion of NORAD leads to chromosomal instability and aneuploidy². NORAD is abundantly expressed in various human cell lines and tissues. Compared to other lncRNAs in mammals, NORAD is highly conserved^2,3. NORAD has been discovered to engage with the proteins that regulate DNA replication and repair mechanisms and translocate to the nucleus when stimulated by DNA damage or replication stress^2,3. NORAD interacts with RBMX, a DNA damage response component, and prevents RNA-binding motif protein, X-linked (RBMX) from assembling at NORAD-activated ribonucleo protein complex 1. NORAD- or RBMX-depleted cells exhibited a higher incidence of chromosomal segregation abnormalities, slower replication fork speed and deregulation of cell cycle progression². Moreover, studies suggest that NORAD is deregulated in breast, ovarian, cervical, gastric, colorectal, bladder, pancreatic, hepatocellular, esophageal, prostate, lung, thyroid, retinoblastoma, and neuroblastoma cancers⁴. Specifically, overexpression of NORAD stimulates proliferation, invasion, and metastasis of cancerous cells and prevents apoptosis⁴. In addition, several lines of evidence suggest that NORAD is associated with chemoresistance to currently available chemotherapeutic agents such as doxorubicin, gemcitabine, and 5-fluorouracil. In neuroblastoma, it has been shown that increased expression of NORAD is enhanced proliferation, metastasis, and doxorubicin resistance and while interfering with the apoptotic death of neuroblastoma cells by inducing HDAC8 expression through sponging miR-144-3p⁵. Also, NORAD has been reported to act as a competing endogenous RNA (ceRNA) to mediate gemcitabine chemoresistance in bladder cancer through regulating WEE1 expression via sponging miR-155-5p⁶. Also, differential activation of NORAD has shown to be associated with the 5-fluorouracil chemoresistance during hypoxia by acting as a ceRNA by sponging miR-495-3p/HIF-1expression in colorectal cancer⁷.

Mitomycin C is a naturally occurring anticancer antibiotic substance derived from streptomyces caespitosus and other streptomyces species. Mitomycin C was discovered in the 1950s by Japanese microbiologists. Mitomycin C is one of the few antibiotics known to react with DNA⁸. It induces DNA damage by introducing monofunctional and bifunctional DNA cross-links. As a prodrug, mitomycin C itself remains inactivated and does not react with DNA and requires bioactivation⁹. The reduction of the quinone ring, which transforms mitomycin c into a highly reactive unstable alkylating species, is required for DNA crosslinking and alkylating activities¹⁰. Mitomycin C is widely used for the treatment of several human malignancies because of its ability to suppress DNA replication and cell division. It has been shown to be an effective antitumor agent in several cancers, including breast cancer, cervical cancer, non-small cell lung cancer, pancreatic cancer, gastric cancer, prostate cancer, and bladder cancer. Mitomycin C is characterized by its high bio-reductive alkylation under hypoxic conditions. Inside solid tumors, oxygen-deprived cells form an environment in which mitomycin c is highly active¹¹.

Although the molecular mechanism underlying the biological and pharmacological properties of mitomycin C is well characterized, its effect on non-coding RNAs activated during the DNA damage response has not yet been described. Accordingly, in this study, we sought to explore the possible role of NORAD, a lncRNA specifically activated during DNA damage response, during mitomycin C-related chemoresistance and mitomycin C-induced DNA damage response.

GİRİŞ

İnsan genomu yüzlerce uzun kodlamayan ribonükleik asidi (RNA) (lncRNA’lar) barındırsa da, farklı biyolojik aktivitelere ve biyokimyasal özelliklere sahip olan sadece yaklaşık bir düzine tanımlanmıştır. DNA hasarına yanıt olarak uyarılan belirli bir lncRNA transkripti olan, DNA hasarıyla aktive edilen kodlamayan RNA’nın (NORAD, eski adıyla LINC00657) genom bütünlüğünün korunması için gerekli olduğu bildirilmiştir¹. NORAD’ın silinmesi kromozomal instabiliteye ve anöploidiye yol açar². NORAD, çeşitli insan hücre dizilerinde ve dokularında bol miktarda eksprese edilir. Memelilerdeki diğer lncRNA’larla karşılaştırıldığında, NORAD yüksek oranda korunmuştur^2,3. NORAD’ın DNA replikasyonu ve onarım mekanizmalarını düzenleyen ve DNA hasarı veya replikasyon stresi ile uyarıldığında çekirdeğe yer değiştiren proteinlerle etkileşime girdiği keşfedilmiştir^2,3. NORAD, bir DNA hasarı tepki bileşeni olan RBMX ile etkileşime girer ve RBMX’in NORAD ile aktive olan ribonükleoprotein kompleks 1’de birleşmesini önler. Deplete edilmiş NORAD veya RBMX hücreler, daha yüksek kromozomal segregasyon anormallikleri, daha yavaş replikasyon çatal hızı ve hücre döngüsü progresyonu deregülasyonu insidansı sergilemişlerdir². Ayrıca, çalışmalar NORAD’ın meme, yumurtalık, servikal, gastric, kolorektal, mesane, pankreas, hepatoselüler, özofagus, prostat, akciğer, tiroid, retinoblastom ve nöroblastom kanserlerinde deregüle olduğunu göstermektedir⁴. Spesifik olarak, NORAD’ın aşırı ekspresyonu, kanserli hücrelerin proliferasyonunu, invazyonu ve metastazını uyarır ve apoptozu önler⁴. Ek olarak, birkaç kanıt dizisi, NORAD’ın doksorubisin, gemsitabin ve 5-florourasil gibi şu anda mevcut kemoterapötik ajanlara karşı kemorezistans ile ilişkili olduğunu göstermektedir. Nöroblastomda, NORAD ekspresyonunun artmasının proliferasyon, metastaz ve doksorubisin direncini arttırdığı ve miR-144-3p sponging yoluyla HDAC8 ekspresyonunu indükleyerek nöroblastom hücrelerinin apoptotik ölümüne müdahale ettiği gösterilmiştir⁵. Ayrıca, NORAD’ın, miR-155-5p sponging yoluyla WEE1 ekspresyonunu düzenleyerek mesane kanserinde gemsitabin kemorezistansına aracılık etmek için rakip bir endojen RNA (ceRNA) olarak hareket ettiği bildirilmiştir⁶. Ayrıca, NORAD’ın diferansiyel aktivasyonunun, kolorektal kanserde miR-495-3p/HIF-1 ekspresyonunu sponging yoluyla ceRNA gibi davranarak hipoksi sırasında 5-florourasil kemorezistans ile ilişkili olduğu gösterilmiştir⁷.

Mitomycin C, Streptomyces Caespitosus ve diğer Streptomyces türlerinden elde edilen, doğal olarak oluşan bir antikanser antibiyotik maddesidir. Mitomisin C, 1950’lerde Japon mikrobiyologlar tarafından keşfedildi. Mitomisin C, DNA ile reaksiyona girdiği bilinen birkaç antibiyotikten biridir⁸. Tek işlevli ve çift işlevli DNA çapraz bağlarını tanıtarak DNA hasarına neden olur. Bir ön ilaç olarak, mitomisin C’nin kendisi inaktif halde kalır ve DNA ile reaksiyona girmez ve biyoaktivasyon gerektirir⁹. Mitomisin C’yi oldukça reaktif, kararsız bir alkilleyici türe dönüştüren kinon halkasının redaksiyonu, DNA çapraz bağlama ve alkilleme aktiviteleri için gereklidir¹⁰. Mitomisin C, DNA replikasyonunu ve hücre bölünmesini baskılama yeteneğinden dolayı birçok insan malignitesinin tedavisinde yaygın olarak kullanılmaktadır. Göğüs kanseri, rahim ağzı kanseri, küçük hücreli olmayan akciğer kanseri, pankreas kanseri, mide kanseri, prostat kanseri ve mesane kanseri dahil olmak üzere çeşitli kanserlerde etkili bir antitümör ajanı olduğu gösterilmiştir. Mitomisin C, hipoksik koşullar altında yüksek biyo-indirgeyici alkilasyonu ile karakterizedir. Katı tümörlerin içinde oksijenden yoksun hücreler mitomisin C’nin oldukça aktif olduğu bir ortam oluşturur¹¹.

Mitomisin C’nin biyolojik ve farmakolojik özelliklerinin altında yatan moleküler mekanizma iyi tanımlanmış olmasına rağmen, DNA hasar yanıtı sırasında aktive olan kodlamayan RNA’lar üzerindeki etkisi henüz tanımlanmamıştır. Buna göre, bu çalışmada, mitomisin C ile ilişkili kemorezistans ve mitomisin C ile indüklenen DNA hasar yanıtı sırasında DNA hasar yanıtında spesifik olarak aktive olan bir lncRNA olan NORAD’ın olası rolünü araştırmaya çalıştık.

MATERIALS AND METHODS

Cell Lines, Culture Conditions, and Chemicals

For the study, HTB-26 (MDA-MB-231) triple negative breast adenocarcinoma cells were obtained from ATCC and propagated using DMEM medium (Cat. No.: D6429, Sigma-Aldrich) complemented with the 1% penicillin/streptomycin and 10% fetal calf serum solution (Cat. No.: A4766801, Sigma-Aldrich). Cell cultures were maintained in moistened carbon dioxide incubator at 37 C. Mitomycin C isolated from Streptomyces caespitosus was commercially obtained from Sigma-Aldrich (Cat. No.: M4287). 2 mg of mitomycin C was suspended in 10 mL ddH₂O to obtain a stock solution of 200 mg/mL.

MTT Analysis

Cells were seeded at a concentration of 3x10⁴ cells/mL in 96-well plates and incubated overnight to determine cell viability. Following overnight incubation, cells were treated with the various concentrations of mitomycin C ranging from 0.125 to 2 mg/mL and incubated for 24 hours. Then, supernatants were discarded, and cells were washed several times with the 1 X PBS solution and subsequently incubated with the 1 mg/mL of MTT (3- (4,5-dimethylthiazol-2-yl) 2,5-diphenyltetrazolium bromide) solution for 40-60 minutes at 37 °C.

Gene Expression Analysis

To investigate the effects of mitomycin C on NORAD expression levels, cells were plated to 12-well culture dishes and incubated overnight to allow attachment. Subsequently, cells were treated with the mitomycin C and incubated for 24 hours. Cells were then harvested using Trypsin-EDTA solution, and RNA purifications were made using GeneJET RNA Purification Kit (Cat. No.: K0702, Thermo Scientific, Waltham, MA, USA) according to the recommendations provided by the manufacturer. RNA quality and concentrations were determined with the help of Thermo Scientific Multiskan GO instrument. The RevertAid First Strand cDNA Synthesis Kit (Cat. No.: FERK1622, Thermo Scientific, Waltham, MA, USA) was used for reverse transcription of RNA samples into cDNA samples. GAPDH and NORAD-specific gene expression PCR primers were designed with the help of NCBI primer blast. Primer pairs for GAPDH were Forward: 5’-AGACCACAGTCCATGCCATCAC-3’, Reverse: 5’-GGTCCACCACCCTGTTGCTGT-3’ and primer pairs for NORAD were Forward: 5’-CAGAGGAGGTATGCAGGGAG-3’, Reverse: 5’-CCACCATCCCCGTGACTAAG-3’. Lastly, to assess gene expression levels of NORAD and GAPDH genes, RealQ Plus 2x Master Mix Green (Cat. No.: A323402, Ampliqon) was used and Rotor-Gene Q real-time PCR instrument was used to perform reactions. Briefly, 12.5 ml RealQ Plus 2x Master Mix, 0.5 ml from each primer (10 mM), 2 ml cDNA and 9.5 ml PCR-grade H₂O were mixed and subjected to following thermal conditions; 15 minutes at 95 C, 40 cycles of 15 s at 94 C, 30 s at 60 C, and 30 s at 70 C. At the end of each reaction, a melting curve analysis was performed between 72 C and 95 C.

Statistical Analysis

For the calculation of relative gene expression levels, 2–^∆Ct formula was used. GAPDH was used as a reference gene for calculations. All experiments were performed in triplicate. Statistical examination of the obtained data was achieved using GraphPad Prism 9 software, with p values less than 0.05 accepted as significant. For comparisons between two independent groups, the Student’s t-test was used whereas variance analysis was used for comparisons of more than two groups.

RESULTS

Cell Viability of Cells Upon Mitomycin C Treatments

Triple negative breast cancer (TNBC) is an aggressive subtype of breast cancer with no effective therapy at present. To explore mitomycin C-related chemoresistance in breast cancer, MDA-MB-231 TNBC was used. Accordingly, MTT assay was used to examine the effect of mitomycin C on viability of breast cancer cells, and cells were treated with the varying concentrations of mitomycin C. Remarkably, the viability of breast cancer cells was found to be dramatically decreased in a dose-dependent manner (Figure 1). Half-maximal inhibitory concentration (IC₅₀)of mitomycin C against MDA-MB-231 breast cancer cells was calculated as 1.12 mg/mL. Treatment with 0.125 mg/mL, 0.25 mg/mL, 0.5 mg/mL, 1 mg/mL and 2 mg/mL mitomycin C for 24 h resulted in 68.72%, 60.86%, 53.20%, 49.27%, and 35.20% cell viability, respectively, compared to the control group (Figure 1). Significant inhibition of cell viability was observed at 1 mg/mL (p<0.0001) and 2 mg/mL (p<0.0001) doses of mitomycin C compared to the untreated group.

Differential Activation of NORAD Upon Mitomycin C Treatments

To further test the influence of mitomycin C on the expression of NORAD lncRNA, we have performed gene expression analysis upon mitomycin C treatments in breast cancer cells. Notably, NORAD expression levels were determined to be significantly enhanced in cells treated with the 1 mg/mL and 2 mg/mL mitomycin C (p<0.0001). Fold-change analysis revealed that expression of NORAD was increased 5.7-fold and 5.2-fold in cells treated with the 1 mg/mL and 2 mg/mL mitomycin C, respectively (Figure 2), strongly indicating that treatment with mitomycin C induces DNA damage response involving NORAD lncRNA.

DISCUSSION

The main goal of cancer treatment is surgical removal of tumor cells or their destruction by radiation or chemotherapy. Therefore, understanding drug-induced genetic alterations and chemoresistance is of great importance for improving patient outcomes in cancer chemotherapy. The poor success of cancer chemotherapy is often due to adverse effects and resistance to chemotherapeutic agents¹². There is increasing evidence that an optimal level of DNA repair is essential for the elimination of mutations and DNA lesions to prevent malignant transformation¹². Thus, DNA repair function emerges as a double-edged sword in cancer treatment. While a low level of DNA repair activity sensitizes cancer cells to chemo-mediated killing, it also allows a second primary tumor to develop¹². In contrast, overactivity of DNA repair functions promotes cancer progression. Maintenance of the genome integrity by DNA damage response and repair mechanisms ensures genomic stability and keeps chromosome number constant. Moreover, lncRNA NORAD is a specific non-coding RNA molecule triggered in response to DNA injury. More recently, NORAD has shown to interact with proteins of DNA replication and repair machinery and migrates to the nucleus in case of stress conditions. NORAD has also been shown to be essential for the assembly of a topoisomerase complex, called NARC1, which is critical for the maintenance of genome stability. NORAD was also shown to sequester PUMILIO proteins to preserve genome integrity^1,13,14. Although NORAD is critical for genomic stability, it has been reported to be a crucial oncogenic driver in human cancers. High activity of NORAD was associated with increased cell proliferation and aggressiveness of human cancers. NORAD was reported to be markedly overexpressed in gastric cancer tissue compared to adjacent healthy tissue. Inhibition of NORAD expression reduced cell viability and migration and promoted apoptotic death of gastric cancer cells by inducing the expression of E-cadherin Bax, and PTEN, and downregulating Bcl-2 proteins¹⁵. NORAD was also determined to be overexpressed in oral squamous cell carcinoma tissues and cell lines, and it functions as a tumor promoter to enhance the advancement of oral squamous cell carcinoma by sponging miR-577¹⁶. Similarly, higher expression of NORAD was found in cancerous tissues of thyroid carcinoma patients, and ectopic overexpression of NORAD was associated with increased cell proliferation, invasion, and migration and activated epithelial-to-mesenchymal transition (EMT) by inhibiting miR-202-5p¹⁷. Knockdown of NORAD was also discovered to be associated with the inhibition of EMT of head and neck cancer stem cells through regulating miR-26a-5p¹⁸. Significant overexpression of NORAD was also found in osteosarcoma tumors and was associated with the clinic and pathological findings of patients, such as tumor size, grade and metastasis¹⁹. Although limited, a relationship between NORAD and resistance to certain types of chemotherapeutic agents has also been demonstrated. Particularly, NORAD has been linked to gemcitabine resistance in bladder cancer by acting as a competitive endogenous RNA that inhibits miR-155-5p activity. Silencing of NORAD in gemcitabine-resistant bladder cancer cells impairs proliferation and cell cycle progression and induces apoptosis via regulation of the miR-155-5p/WEE1 axis⁶. In addition, NORAD was shown to be associated with the hypoxia-induced 5-fluorouracil chemoresistance in colorectal cancer⁷. Consistent with all these observations, in the present study, it has been shown that NORAD was significantly activated in response to mitomycin C treatment in breast cancer cells, suggesting that NORAD may be related to mitomycin C resistance at the organism level. NORAD inhibitory therapy in combination with mitomycin C chemotherapy could be a good treatment method for triple negative breast cancer. Overall, the strong tumor-promoting function and association with chemoresistance to certain drugs also support a role for NORAD in chemoresistance to mitomycin C.

Study Limitations

While this study successfully evaluated the role of NORAD in mitomycin C-related chemoresistance and mitomycin C-induced DNA damage response, there were some limitations. In the future studies, gain of function and loss of function experiments of NORAD along with the mitomycin treatments are of great interest to understand more about the role of NORAD during DNA damage response and repair.

TARTIŞMA

Kanser tedavisinin temel amacı, tümör hücrelerinin cerrahi olarak çıkarılması veya radyasyon veya kemoterapi ile yok edilmesidir. Bu nedenle, ilaca bağlı genetik değişiklikleri ve kemorezistansı anlamak, kanser kemoterapisinde hasta sonuçlarını iyileştirmek için büyük önem taşımaktadır. Kanser kemoterapisinin zayıf başarısı genellikle yan etkilerden ve kemoterapötik ajanlara dirençten kaynaklanmaktadır¹². Malign transformasyonu önlemek için mutasyonların ve DNA lezyonlarının ortadan kaldırılması amacıyla optimal bir DNA onarımı seviyesinin gerekli olduğuna dair artan kanıtlar vardır¹². Böylece DNA onarım fonksiyonu kanser tedavisinde iki ucu keskin bir kılıç olarak karşımıza çıkmaktadır. Düşük düzeyde DNA onarım aktivitesi, kanser hücrelerini kemo-aracılı ölüme duyarlı hale getirirken, aynı zamanda ikinci bir birincil tümörün gelişmesine de izin vermektedir¹². Buna karşılık, DNA onarım işlevlerinin aşırı aktivitesi, kanserin ilerlemesini destekler. DNA hasar yanıtı ve onarım mekanizmaları ile genom bütünlüğünün korunması, genomik stabiliteyi sağlar ve kromozom sayısını sabit tutar. Ayrıca, lncRNA NORAD, DNA hasarına yanıt olarak tetiklenen, kodlamayan spesifik bir RNA molekülüdür. Daha yakın zamanlarda, NORAD’ın, DNA replikasyonu ve onarım mekanizmasının proteinleri ile etkileşime girdiği ve stres koşulları durumunda çekirdeğe göç ettiği gösterilmiştir. NORAD’ın ayrıca, genom stabilitesinin korunması için kritik olan NARC1 adı verilen bir topoizomeraz kompleksinin oluşumu için gerekli olduğu gösterilmiştir. NORAD’ın ayrıca genom bütünlüğünü korumak için PUMILIO proteinlerini ayrı tuttuğu da gösterilmiştir^1,13,14. NORAD, genomik stabilite için önemli olmasına rağmen, insan kanserlerinde çok önemli bir onkojenik sürücü olarak bildirilmiştir. NORAD’ın yüksek aktivitesi, artan hücre proliferasyonu ve insan kanserlerinin agresifliği ile ilişkilendirilmiştir. NORAD’ın, komşu sağlıklı dokuya kıyasla mide kanseri dokusunda belirgin şekilde aşırı eksprese edildiği rapor edilmiştir. NORAD ekspresyonunun inhibisyonu, hücre canlılığını ve göçünü azalttığı ve E-cadherin Bax ve PTEN ekspresyonunu indükleyerek ve Bcl-2 proteinlerini aşağı regüle ederek mide kanseri hücrelerinin apoptotik ölümünü desteklediği bulunmuştur¹⁵. NORAD’ın ayrıca oral skuamöz hücreli karsinom dokularında ve hücre dizilerinde aşırı eksprese edildiği belirlenmiş ve miR-577 sponging yoluyla oral skuamöz hücreli karsinomun ilerlemesini arttırmak için bir tümör promotörü olarak işlev gördüğü ifade edilmiştir¹⁶. Benzer şekilde, tiroid karsinomu hastalarının kanserli dokularında NORAD’ın daha yüksek ekspresyonu bulunmuş ve NORAD’ın ektopik aşırı ekspresyonu artan hücre proliferasyonu, invazyonu ve göçünde artış ile ilişkilendirilmiş ve miR-202-5p’yi inhibe ederek epitelyal-mezenkimal geçişi (EMT) aktive etmiştir¹⁷. NORAD’ın yıkılmasının, miR-26a-5p’yi düzenleyerek baş ve boyun kanseri kök hücrelerinin EMT’sinin inhibisyonu ile ilişkili olduğu da keşfedilmiştir¹⁸. NORAD’ın önemli aşırı ekspresyonu osteosarkom tümörlerinde de bulundu ve hastaların tümör boyutu, derecesi ve metastazı gibi klinik ve patolojik bulguları ile ilişkilendirildi¹⁹. Sınırlı olmasına rağmen, NORAD ile belirli kemoterapötik ajan tiplerine direnç arasında bir ilişki de gösterilmiştir. Özellikle NORAD, miR-155-5p aktivitesini inhibe eden rekabetçi bir endojen RNA olarak hareket ederek mesane kanserinde gemsitabin direncine bağlanmıştır. NORAD’ın gemsitabine dirençli mesane kanseri hücrelerinde susturulması, proliferasyonu ve hücre döngüsü progresyonunu bozmakta ve miR-155-5p/WEE1 ekseninin regülasyonu yoluyla apoptozu indüklemektedir⁶. Ek olarak, NORAD’ın kolorektal kanserde hipoksi ile indüklenen 5-florourasil kemorezistans ile ilişkili olduğu gösterilmiştir⁷. Tüm bu gözlemlerle tutarlı olarak, bu çalışmada meme kanseri hücrelerinde mitomisin C tedavisine yanıt olarak NORAD’ın önemli ölçüde aktive olduğu gösterilmiştir, bu da NORAD’ın organizma düzeyinde mitomisin C direnci ile ilişkili olabileceğini düşündürdü. Mitomisin C kemoterapisi ile kombinasyon halinde olarak NORAD inhibitör tedavisi, TNBC için iyi bir tedavi yöntemi olabilir. Genel olarak, güçlü tümör teşvik edici işlev ve belirli ilaçlara karşı kemorezistans ile olan ilişki, NORAD’ın aynı zamanda mitomisin C’ye karşı kemorezistanstaki rolünü desteklemektedir.

Çalışmanın Kısıtlılıkları

Bu çalışma, NORAD’ın mitomisin C ile ilişkili kemorezistans ve mitomisin C ile indüklenen DNA hasar yanıtındaki rolünü başarıyla değerlendirirken, bazı sınırlamalar vardı. Yapılacak olan çalışmalarda, mitomisin tedavileri ile birlikte NORAD’ın fonksiyon kazanımı ve fonksiyon kaybı deneyleri, NORAD’ın DNA hasar yanıtı ve onarımındaki rolünü daha iyi anlamak için ilgi görecektir.

CONCLUSION

In conclusion, we describe here that lncRNA NORAD was activated in response to mitomycin C treatments in TNBC cells, strongly indicating that NORAD may relate to the mitomycin C-related chemoresistance. However, these findings need to be supported by additional comprehensive studies.

Ethics

Ethics Committee Approval: The study was performed in cancer cell lines; therefore, ethical approval was not required.

Informed Consent: Not applicable for the present study.

Peer-review: Externally and internally peer-reviewed.

Financial Disclosure: The author declared that this study received no financial support.

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