Autophagy is a conserved catabolic process in which cytosolic macromolecules, lipid droplets, labeled proteins, and damaged organelles are recycled via a lysosome-mediated digestion process. This mechanism is normally important for cellular survival and maintenance of energy homeostasis (1). It also establishes cellular adaptations in response to stressful conditions (2). Autophagy is a highly regulated process and can be influenced by aging, oxygen, nutrients and diseases, especially cancers (3).

Promoting autophagy requires the activation of the ULK initiation complex, which is mainly composed of UNC-51-like kinase 1 (ULK1), autophagy-related factor 13 (ATG13), and focal adhesion kinase family interacting protein of 200 kD (FIP200). Once activated, an autophagosome forms to initiate the autophagy process (4,5). ULK complex is under the direct inhibition of the mechanistic target of rapamycin complex 1 (mTORC1), which is highly activated under nutrient-rich conditions (6). On the other hand, the inhibition of mTORC1 over the ULK complex is released under starvation and stressful conditions, which in turn activates autophagy as a survival mechanism (6). Cancer malignant traits, such as increased proliferation and residency in oxygen and nutrient-deprived environments, require alterations in their metabolic activities, enabling cancerous cells to adapt to stressful conditions (7). Among several factors involved in metabolic reprogramming, autophagy has been found to play a crucial role in cancer initiation, progression and chemoresistance (8). The interplay between autophagy and cancer is complicated and contradictory, as it has been previously reported that autophagy plays a bipolar role in cancer progression and operates differently at different stages of cancer progression (9,10). Seemingly, the opposing roles of autophagy are observed in the prevention of early tumor development vs. the maintenance and metabolic adaptation of established and metastasizing tumors to promote cellular survival (11).

Recently, researchers have focused on enhancing tumor sensitivity to chemotherapy by targeting autophagy. However, this approach is complicated by the biphasic role of autophagy in cancer progression; inhibiting it may suppress tumor survival but could also eliminate its tumor-suppressive effects in early stages (2). Therefore, the timing and tumor context are critical in choosing the appropriate autophagy intervention. In advanced cancers, inhibiting autophagy may be more effective, whereas inducing it in apoptosis-resistant tumors could promote cancer cell death (12). These findings underscore that autophagy-targeted therapies should be personalized, depending on cancer type and stage (2,12). Combination therapies that use autophagy inhibitors, such as hydroxychloroquine or chloroquine, alongside standard anticancer medications, are being assessed in numerous clinical trials (13-15). However, targeting specific molecular nodes within the autophagy pathway, such as ULK1, rather than using nonspecific pharmacological agents, may help minimize adverse effects on normal cells and provide more precise regulation (16).

A growing theory on the variety of ULK1 functions pinpoints its critical role in several non-canonical processes, primarily cellular fate determination, metabolic reprogramming, stress response, and disease development, particularly cancers (17,18). The mitotic delay and increased cell death observed after ULK1 knockdown likely result from both impaired autophagy and ULK1's autophagy-independent roles in mitosis, including regulation of centrosome dynamics, spindle assembly, and proper chromosome segregation, suggesting that defects in cell division may substantially contribute to the phenotype. Based on a previous study, cells are exposed to extreme oxidative stress when ULK1 is inhibited. This is because of the metabolic shifting from glycolysis to the utilization of mitochondrial oxidative phosphorylation as an alternative mechanism (19). Accordingly, LKB1 mutant lung cancer cells are then re-sensitized to overcome chemoresistance by the oxidative phosphorylation associated with ULK1 inhibition (20). On the other hand, Deng et al (20) suggested that trametinib, a MAPK1/3 kinase inhibitor, prevents bone metastases in MDA-MB-231 breast cancer (BC) by reestablishing mitophagy function through upregulating ULK1 activity. Away from its role in autophagy induction, ULK1 has also been demonstrated to influence chromosomal segregation and mitotic spindle organization during cell division. Thereafter, inhibition of ULK1 resulted in defective chromosome alignment and delayed mitosis. This suggests that ULK1 controls mitotic integrity, which is essential for the advancement of the cell cycle and the proliferation of cancer cells (21).

The ability of cancer cells to orchestrate autophagy flux is extended beyond the genetic expression of autophagy-related genes via several epigenetic and posttranslational modification mechanisms, including ubiquitination and de-ubiquitination processes (7). Several autophagy-related factors were found to be either ubiquitinated or de-ubiquitinated in favor of cancer development and spread. Interestingly, distinct cancer types express distinct ubiquitination/de-ubiquitination enzymes, and different tissue types have varied roles for these enzymes. Accordingly, it has been shown that activated ULK1 (or ULK-1) is further stabilized, and the basal level of autophagy is maintained when the de-ubiquitination peptidase USP20 removes ubiquitin from it, thereby preventing its degradation. Moreover, USP20 upregulation was found to be associated with various cellular biological processes such as cell cycle progression, proliferation, migration and invasion, playing a pivotal role in tumorigenesis (22). It has been hypothesized that under prolonged starvation, the interaction between USP20 and ULK1 is reduced to terminate autophagy, a protective response that drives the cell away from apoptosis (22). These data suggest that modulating proteolytic ubiquitination of ULK1 via USP20 may be effective to bypass cancerous chemoresistance and may play a role in deciding cellular fate, based on the fact that persistent enhancement of autophagy could be a successful strategy that drives cellular death and apoptosis in different cancer types and sensitizes tumors to chemotherapeutic drugs.

As a mechanism that may be directly or indirectly involved in deciding the fate of the cell, either survival or death (3), it is necessary to ascertain where and when autophagy contributes to or inhibits tumor development and progression in different cancer types. This is fundamental to establish autophagy as a potential therapeutic target for personalized medication in different cancer types. Moreover, understanding the dynamic conversion between ubiquitination and de-ubiquitination status in different cancer types, especially those related to the autophagy process, may provide novel insights and new treatment candidates for cancer therapy strategies. In the current study, it was aimed to perform this task by measuring levels of basal autophagy flux in different human cancer cell lines. Furthermore, a new system for selective inhibition of autophagy was established using siRNA gene silencing technology for both ULK1 and USP20, to evaluate the potential role of autophagy inhibition on the fate of different cancer types when combined with conventional therapeutic agents. This system will also be evaluated for its efficiency in sensitizing different multi-drug-resistant cancer types to their selective commercially available chemotherapeutic drugs.

Autophagy is a homeostasis maintenance mechanism that aims to prevent the accumulation of damaged cellular components or compartments and maintain cellular balance. Besides its canonical functions in the cell, it is well known to have several noncanonical functions that affect numerous vital cellular responses (24). In cancers, it has been postulated that autophagy plays an important role in reprogramming the cell, modulating cellular responses to chemotherapy and determining cellular fate, either survival or death. However, the available data were controversial and the effect of autophagy on cancer progression and therapy effectiveness was not the same for different cancer types and remained unclearly defined. At present, to the best of our knowledge, the data that precisely dissect the functional classification of autophagy in different cancer types are still lacking and need to be further clarified. The aim of the present study was to uncover the functional role of autophagy in a number of cancer cell lines by specifically evaluating its role in cancer cell fate and its responses to the conventional chemotherapeutic agents. Direct evidence that autophagy is differentially modulated in different cancer cell lines for the sake of cancer survival was provided. Powerful evidence was also presented that autophagy inhibition is directly correlated with cancer cellular fates by being a cytoprotective or cytotoxic mechanism. Furthermore, the precise correlation between autophagy inhibition and the desensitization or resensitization of different investigated cancer cells toward conventional therapies was determined. Furthermore, it has been successfully validated that the autophagy-related initiation factor, ULK1, and its de-ubiquitinase stabilizing enzyme, USP20, are powerful potential targets for the treatment of cancers. ULK1 was selected as the central autophagy reference molecule because of its established, indispensable role in initiating the autophagy cascade. USP20 was chosen as a parallel target because of its potential but understudied role as a de-ubiquitinase that may regulate ULK1 turnover and activity, thereby revealing a novel post-translational mechanism that could reshape the understanding of autophagy regulation.

The data of the present study demonstrated that ULK1 and USP20 expression varies among cancer cells, with either low or high expression levels. Among the tested cells, ULK1 was mostly expressed in the MCF-7 BC cell line, while the minimum expression was detected in U87 glioblastoma cells. This variability in the expression reflects the different dependence of cancer cells on the autophagy pathway and may relate to chemoresistance, metastasis and the fate of the cells. The data of the present study are in line with other studies, where it has been previously postulated that ULK1 is overexpressed in MCF-7 cells, while lowly expressed in MDA-MB-231 cells (25). It has been indicated that overexpression of ULK1 is conversely correlated with the prognosis in a number of cancer types, including BC (26). Interestingly, low expression of ULK1 in MDA-MB231 has been correlated with more metastatic behavior, while overexpression of ULK1 appears to be protective against metastasis. This is because ULK1 is required to phosphorylate and inhibit Exo70, an essential component of the exocyst complex, which is necessary for invasion and metastasis (25). However, this differential expression of ULK1 appears to affect the sensitivity of cancer cells to doxorubicin. In the MCF-7 cell line, the high expression level of ULK1 confers greater sensitivity to doxorubicin compared with the MDA-MB-231 cell line. However, when ULK1 was suppressed, MCF-7 cells exhibited more aggressive behavior and became desensitized to the drug. On the other hand, MDA-MB-231 is more resistant to doxorubicin when compared with MCF-7 but becomes more vulnerable to the drug when ULK1 is depressed. This can be explained as the minimum level of ULK1 in MDA-MB-231 cells is essential to maintain the aggressive behavior, but when it is suppressed, the cells lose these aggressive traits.

Interestingly, the opposing effects of ULK1 on doxorubicin sensitivity in MCF-7 vs. MDA-MB-231 cells likely reflect its context-dependent roles in autophagy and apoptosis. In MCF-7 cells, high basal ULK1 supports autophagy that facilitates stress-induced apoptosis; therefore knockdown reduces doxorubicin sensitivity. Conversely, in MDA-MB-231 cells, basal autophagy may be primarily cytoprotective, and ULK1 knockdown disrupts this survival mechanism, sensitizing cells to treatment. These differences are influenced by cell-type-specific factors, including p53 status, baseline autophagic flux, and apoptotic wiring, highlighting ULK1 as a versatile regulator whose impact on chemotherapy response is highly context-dependent. Furthermore, a context-dependent approach to ULK1 modulation may be more effective than uniform inhibition. In highly aggressive or metastatic cancers, such as MDA-MB-231, ULK1 and USP20 appear to restrain pro-metastatic programs, suggesting that ULK1 activation could suppress invasion and metastasis. Conversely, in tumors where ULK1 supports cytoprotective autophagy, inhibition may enhance chemosensitivity. Therefore, therapeutic strategies should be guided by cell-type-specific autophagy dependency, basal ULK1/USP20 expression and metastatic potential, with activation or inhibition tailored to exploit the tumor's particular vulnerabilities while minimizing harm to normal tissues.

Tang et al (27) previously reported that ULK1 is overexpressed in non-small cell lung cancer cells (NSCLC), compared with normal lung cells and this is correlated with poor prognosis and patients' survival rate. Inhibition of ULK1 with SBI0206965, a selective ULK1 inhibitor, reversed the aggressive trait of these cells and sensitized cells to cisplatin. The data of the present study showed different outcomes, as ULK1 appears to prevent the progression of the disease, and when it is inhibited, A549 cells become more aggressive and resistant to cisplatin. However, the correlation between ULK1 and drug-resistant genes must be further investigated to understand the mechanism underlying these results. The apparent contradiction between the present study's findings in A549 cells and those reported by Tang et al (27) likely reflects differences in both inhibition strategy and cellular context. Tang et al (27) employed the small-molecule ULK1 inhibitor SB10206965, which may affect ULK1 kinase activity without fully depleting protein levels or disrupting its scaffolding functions, whereas siRNA-mediated knockdown was used in the present study, leading to a more complete loss of ULK1 protein and potentially broader effects on autophagy-independent roles such as mitotic regulation. Additionally, NSCLC encompasses heterogeneous subtypes with distinct basal autophagy flux, stress-response pathways and genetic backgrounds, all of which can influence the outcome of ULK1 inhibition on cisplatin sensitivity. Taken together, these methodological and biological differences likely account for the divergent results and underscore the context-dependent nature of ULK1 function in chemotherapy response.

USP20 has been positively correlated to the development and progression of cancers. It has been reported that USP20 is differentially expressed between cancer and normal cells, being highly expressed in most cancers compared with their corresponding normal cells but found to be lowly expressed in a few cancer types, including pancreatic cancers (28). Inconsistent with the previous findings, the results of the present study are similar in the context of USP20 expression level. Moreover, it has been reported that USP20 is responsible for the stabilization of the labile SNAI2/SLUG, which is a transcription factor that drives invasion and metastasis in cancers (29). When USP20 was inhibited, SNAI2/SLUG was subjected to degradation after being ubiquitinated, which in turn inhibited tumor progression (29). Consistently, the results of the present study indicate that USP20 inhibition re-sensitized numerous cancer types to their corresponding chemotherapies, including MCF-7, HepG2, A549 and PanC1, and enhanced the effectiveness of the chemotherapy. By contrast, the triple-negative MDA-MB-231 BC and U87 glioblastoma cell lines behaved differently, as they remained unchanged or became highly resistant to doxorubicin, respectively. Overall, USP20 knockdown sensitizes MCF-7 cells but not MDA-MB-231 cells, likely reflecting cell-type-specific dependencies. The highly metastatic, triple-negative MDA-MB-231 cells may rely on USP20-independent pathways to maintain survival and invasion, using alternative de-ubiquitinases or signaling networks to stabilize pro-metastatic factors like SNAI2/SLUG. This highlights the context-dependent role of USP20 and the plasticity of survival mechanisms in aggressive BC. A comprehensive proteomic, metabolomic, and transcriptomic study must be performed to widen the understanding of the mechanisms underlying ULK1 and USP20 modulation and the chemotherapeutic sensitivity of different cancer cell lines.

The present study determined whether chemotherapeutic medications alter autophagy-related genes including P62, USP20 and ULK1. In liver cancer HepG2 cells and glioblastoma U87 cells, doxorubicin treatment leads to downregulation of ULK1 and USP20 expression levels and the overexpression of P62, suggesting the inhibition of autophagy. Although autophagy induction is a well-described response to chemotherapeutic stress, the present findings indicated that doxorubicin can also suppress autophagy in a cell-type-dependent manner, as reflected by ULK1 downregulation and p62 accumulation in HepG2 and U87 cells. These seemingly opposing outcomes can be reconciled by recognizing that chemotherapy produces biphasic and context-specific autophagy responses. At early or lower doses, genotoxic stress typically activates p53-, NF-κB-, and MAPK-driven transcriptional programs that stimulate autophagy as a cytoprotective mechanism. However, prolonged or high-dose exposure can overwhelm cellular proteostasis, impair lysosomal function, or promote ULK1 degradation, resulting in blocked autophagic flux despite transcriptional activation of stress-responsive genes. Thus, doxorubicin may either induce or inhibit autophagy depending on dose, timing, and the intrinsic stress-response architecture of each cell line, explaining why HepG2 and U87 exhibit autophagy suppression while other models demonstrate induction. Interestingly, the observations made in the present study suggested that in U87 glioblastoma cells, basal autophagy maintained by ULK1 and USP20 may be pro-death rather than cytoprotective. Inhibition of these autophagy regulators reduces stress-induced autophagic activity, which in this context appeared to facilitate doxorubicin-induced apoptosis. Consequently, knockdown of ULK1 or USP20 diminishes pro-death autophagy, allowing cells to survive chemotherapy, consistent with the notion that the functional outcome of autophagy is highly context- and cell-type-dependent. These findings highlight that in aggressive cancer types such as glioblastoma, basal autophagy can act as a tumor-suppressive, pro-apoptotic mechanism.

According to Sha et al (30), an elevated P62 level indicates a compromised proteasomal function in cells. Moreover, doxorubicin treatment markedly increased the level of P62 transcripts in MDA-MB-231, indicating that autophagy is being inhibited in the cells, but it did not affect the expression of ULK1 or USP20. These findings could be explained by the fact that autophagy occurs through a variety of routes inside the cell and that autophagy-mediating factors other than ULK1 and USP20, including ATG12 and ATG7, may be downregulated in response to the drug. Another research group demonstrated that chemotherapy treatment of liver cancer HepG2 cells increases autophagy flux, dictated by an increase in LC3II level (31). Their outcome contradicts the findings of the present study; however, the chemotherapeutic agents evaluated in their study were 5-fluorouracil and cisplatin, but not doxorubicin, which was used in the present study, suggesting that different chemotherapies operate with different mechanisms.

Chemotherapeutic agents such as doxorubicin and cisplatin appear to transcriptionally upregulate ULK1, USP20, and P62 through activation of stress-responsive signaling pathways. Both drugs induce substantial DNA damage, oxidative stress and ER stress, which activate transcription factors including p53, NF-κB, ATF4/CHOP and Nrf2. These regulators are well known to drive the expression of autophagy-related genes as part of a compensatory cytoprotective response. In parallel, activation of the DNA damage-response kinases (ATM/ATR) and MAPK pathways further enhances transcription of autophagy initiation factors and stress adaptors. As a result, doxorubicin and cisplatin promote a coordinated upregulation of ULK1, USP20, and P62 to enhance autophagy and maintain cellular homeostasis under chemotherapeutic stress.

Cisplatin was confirmed to induce ULK1 expression in lung cancer A549 cells, and this elevation was correlated with poor prognosis and the development of the cisplatin-resistant trait. When ULK1 was knocked down, A549 became sensitized to cisplatin and underwent apoptosis (27). Conversely, the highest tested concentration of cisplatin in the present research did not affect ULK1 expression, accompanied by an elevation of P62 expression, indicating an impaired autophagy process. When ULK1 was knocked down, resistance to cisplatin was developed. Suggesting that the presence of ULK1 and a functional autophagy process is important for effective chemotherapy treatment. Interestingly, USP20 becomes elevated upon cisplatin employment in A549 cells. It has been indicated that USP20 high levels promote cell proliferation, migration and invasion, and are directly correlated with poor prognosis and survival rates (22). These data are in line with our data, as USP20 knockdown leads to higher sensitivity of A549 to cisplatin.

Regarding the pancreatic PanC1 cells, gemcitabine chemotherapy massively induced ULK1 expression. However, the induction of autophagy in this case appears to be important for PanC1 survival after their exposure to gemcitabine, evidenced by the enhanced sensitivity of PanC1 to the drug after siULK1 administration. Accordingly, one research group indicated that gemcitabine acts by inhibiting the replication of DNA and inducing its damage, and as a survival response, PanC1 cells induced autophagy and the lysosomal functions upon drug exposure (32). The therapeutic efficiency of this drug is highly limited due to the development of drug resistance by the growing pancreatic cancers (33). Seemingly, PanC1 develops this resistance by inducing autophagy as a survival mechanism to recycle gemcitabine-induced damage in the cellular components and enhance cell growth (34). Thus, inhibiting autophagy along with gemcitabine administration may enhance therapeutic effectiveness against the disease.

Although the present study focused on single-agent chemotherapy, ULK1/USP20 modulation could influence combination therapies in a context-dependent manner. Inhibiting ULK1/USP20 may sensitize tumor cells to targeted therapies by blocking cytoprotective autophagy, while activating ULK1 in pro-death contexts could enhance immunotherapy by promoting immunogenic cell death. Careful consideration of tumor subtype, basal autophagic flux, and immune status will be essential to optimize such combination strategies.

The fate of cancer cells when they are exposed to chemotherapeutic treatment is governed by the complicated relationship between apoptosis and autophagy, processes that may operate synergistically or antagonize each other (35). Apoptosis is initiated by extrinsic ligands or intrinsic cellular stresses, such as reactive oxygen species, DNA damage and mitochondrial stress (36). The balance between the BCL-2 family proteins, mainly the proapoptotic protein Bax and the antiapoptotic protein BCL-2, dictates the fate of the cell, either survival or death (37). However, studies that investigate the correlation between ULK1, USP20, and apoptosis in cancers are contradictory and minimal, especially for USP20. For this aim, the dynamic relationship between the autophagy-related gene, ULK1, the de-ubiquitinating enzyme USP20, and apoptosis is further clarified in the present study. Although autophagy is widely known to antagonize apoptotic cell death, it can operate hand in hand with apoptosis, specifically after persistent exposure to stressful conditions (35). This contradictory function of autophagy over apoptotic proteins can be observed in the present study. When ULK1 was inhibited in the investigated cancer cell lines, the latter showed variable responses regarding apoptosis induction. Chemotherapeutic agents also show different patterns and magnitudes in inducing apoptosis and exhibit different mechanisms that drive cellular death.

Accordingly, knockdown of ULK1 or USP20 likely disrupts autophagic homeostasis, leading to the accumulation of damaged organelles and cellular stress, which can trigger the intrinsic apoptotic pathway. Specifically, autophagy inhibition may promote mitochondrial dysfunction, resulting in the release of cytochrome c and subsequent activation of pro-apoptotic proteins such as Bax, while suppressing anti-apoptotic Bcl-2, thereby shifting the Bax/Bcl-2 ratio in favor of apoptosis. This mechanistic link is consistent with prior reports demonstrating that impaired autophagy sensitizes cells to mitochondrial mediated apoptosis. Furthermore, doxorubicin induces cellular apoptosis in BC cell lines, MCF-7 and MDA-MB-231, and the glioblastoma U87 cell line. On the contrary, doxorubicin treatment of liver cancer HepG2 cells inhibited the apoptotic pathway but enhanced the necrotic pathway. Necrosis is another uncontrolled cell death mechanism, which involves molecular mechanisms other than Bax and Bcl-2(38).

Knockdown of USP20 also shows variable effects on cancerous cells' fate. In a previous study, the knockdown of USP20 in the HeLa cervical cancer cell line promoted cellular survival and growth by stabilizing P62, and activating the TNFα/NF-κB survival pathway (39). When USP20 was depleted, apoptosis was induced in HeLa cells (39). Furthermore, USP20 prevents the lysosomal degradation of ULK1 and thus enhances the operation of autophagy under starvation conditions (40), and its depletion reduces autophagy and drives apoptosis (40). These data reflect the complex relationship between these factors and apoptosis, as they may intersect at numerous points within different cellular pathways. Altogether, cancer cell fate after combining chemotherapy with ULK1 or USP20 silencing depends on the dynamic balance between Bax and Bcl-2 triggered by both treatments. Thus, the effect of ULK1 and USP20 silencing on the apoptotic pathway may antagonize and reduce the effectiveness of the conventional chemotherapy in some cancer types but synergize and augment the apoptotic effect of chemotherapies in other cancer cells.

Primary fibroblasts proliferate reliably, maintain a stable karyotype, and are easier to culture than many primary epithelial cells. This ensures reproducible comparisons across experiments. In addition, HDFa cells lack the constitutive stress, metabolic rewiring, and proliferative signaling that often complicate the interpretation of cancer cell lines (41). This makes them a useful baseline for identifying cancer-associated upregulation of proteins such as ULK1 and USP20. ULK1 and USP20 expression are highly tissue-dependent. Some tissues naturally express higher or lower levels of autophagy regulators (42,43). Tissue-matched controls might show that certain cancer cell lines do not overexpress ULK1 or USP20 when compared with their native tissue.

Regarding the therapeutic implications, the context-dependent effects of ULK1 inhibition indicate that careful patient stratification is necessary to achieve a therapeutic window. Tumors with high basal ULK1 expression or elevated autophagic flux may be more dependent on ULK1 for survival, whereas normal tissues with lower flux, such as fibroblasts, may be spared. Additional factors, including p53 status, apoptotic priming, and expression of co-regulators such as USP20, could further refine predictions of ULK1 dependency. Assessing tumor subtype, metastatic potential, and markers of oxidative stress or metabolic rewiring may also help identify cancers that are particularly sensitive to ULK1 inhibition, allowing selective targeting of tumor cells while minimizing toxicity to normal tissue.

While the findings of the present study provide valuable results, some limitations can be addressed. Nevertheless, the involvement of more cell line types would broaden our understanding of the multifaceted role of autophagy. Furthermore, the present study compared the changes in the expression of ULK1 and USP20 in cancer cell lines relative to normal skin fibroblast cells only. However, it would be more accurate to correlate the changes in their expression with the normal cells of the same type as the cancer cells. Another limitation of the present study is that the autophagic flux at the protein level was not directly assessed, as the antibodies for LC3 and p62 tested were non-specific. Therefore, while the mRNA measurements provided insight into transcriptional regulation of autophagy-related genes, they may not fully reflect functional autophagic activity. Additionally, a potential limitation was that siRNA reagents can produce off-target or immune-stimulatory effects. While all knockdowns were compared with a scrambled siRNA control, some residual non-specific effects, such as modest IC₅₀ shifts in fibroblasts, cannot be fully excluded and should be considered when interpreting the data.

In conclusion, the present study provided a detailed dataset that reflects the biphasic role of autophagy among different cancer types. ULK1 and USP20 are differentially expressed among different cancer types, and their knockdown is directly correlated with chemoresistance of cancer cells toward the conventional chemotherapeutic drugs. The presented data indicate that different cancer cells react in various ways when ULK1 and USP20 are silenced in the context of cellular death. The available data help us determine where the inhibition of these genes can be incorporated with conventional therapy to improve its effectiveness and where it must be avoided to prevent the development of more aggressive tumor characteristics. Further studies should be conducted to uncover the molecular mechanisms underlying the differential role of autophagy in these cancers, involving a comprehensive metabolomics, transcriptomics, and proteomics analysis. Also, key in vivo studies should use xenograft or patient-derived models to test genetic or pharmacologic inhibition of ULK1 and USP20 alongside chemotherapy, assessing tumor growth, apoptosis, and drug response. Metastatic models can determine effects on invasion and metastasis, while toxicity studies ensure safety. Linking ULK1/USP20 expression and autophagy or apoptosis markers with treatment outcomes will confirm target engagement and support their therapeutic potential.