Tick infestations transmit various infectious agents and result in significant socioeconomic consequences. Currently, the primary focus of tick control efforts is identifying potential targets for immune intervention. In a previous study, we identified a highly conserved protein abundant in tick haemolymph extracellular vesicles (EVs) known as translationally controlled tumour protein (TCTP). We have found that native TCTP is present in various tissues of the Rhipicephalus haemaphysaloides tick, including salivary glands, midgut, ovary, and fat body. Notably, TCTP is particularly abundant in the tick ovary and its levels increase progressively from the blood-feeding stage to engorgement. When the TCTP gene was knocked down by RNAi, there was a noticeable delay in ovarian development, and the reproductive performance, in terms of egg quantity and survival, was also hindered. Our investigations have revealed that the observed effects in ovary and eggs in dsRNA-treated ticks are not attributable to cell death mechanisms like apoptosis and autophagy but rather to the reduction in the expression of vitellogenin (Vg1, Vg2, and Vg3) and ferritin (ferritin 1 and ferritin 2) proteins crucial for ovarian development and embryo survival in ticks. Additionally, phylogenetic analysis and structural comparisons of RhTCTP and its orthologues across various tick species, vertebrate hosts, and humans have shown that TCTP is conserved in ticks but differs significantly between ticks and their hosts, particularly in the TCTP_1 and TCTP_2 domains. Overall, TCTP plays a vital role in tick reproductive development and presents itself as a potential target for tick control in both humans and animals.

The target of rapamycin (TOR) kinase serves as a central regulator that integrates nutrient and energy signals to orchestrate cellular and organismal physiology in both animals and plants. Despite significant advancements having been made in understanding the molecular and cellular functions of plant TOR kinases, the upstream regulators that modulate TOR activity are not yet fully elucidated. In animals, the translationally controlled tumor protein (TCTP) is recognized as a key player in TOR signaling. This study reveals that two TCTP isoforms from Cucumis sativus, when introduced into Arabidopsis, are instrumental in balancing growth and defense mechanisms against the fungal pathogen Golovinomyces cichoracearum. We hypothesize that plant TCTPs act as upstream regulators of TOR in response to powdery mildew caused by Podosphaera xanthii in Cucumis. Our research further uncovers a stable interaction between CsTCTP and a small GTPase, CsRab11A. Transient transformation assays indicate that CsRab11A is involved in the defense against P. xanthii and promotes the activation of TOR signaling through CsTCTP. Moreover, our findings demonstrate that the critical role of TOR in plant disease resistance is contingent upon its regulated activity; pretreatment with a TOR inhibitor (AZD-8055) enhances cucumber plant resistance to P. xanthii, while pretreatment with a TOR activator (MHY-1485) increases susceptibility. These results suggest a sophisticated adaptive response mechanism in which upstream regulators, CsTCTP and CsRab11A, coordinate to modulate TOR function in response to P. xanthii, highlighting a novel aspect of plant-pathogen interactions.

Translationally controlled tumor protein (TCTP) is a highly conserved multifunctional protein, which participates in many important physiological processes. Recently, the roles of TCTP in cell proliferation and apoptosis, especially its close relationship with various tumors, have attracted widespread attention. In this study, we found that the protein level of TCTP was significantly reduced in acute promyelocytic leukemia cell line NB4 transfected with retinoic acid-induced gene G (RIG-G). The RIG-G was found in our previous work as a key mediator of anti-proliferative activity in retinoid/interferon-related pathways. Here, we tried to further explore the function of TCTP in the development of acute myeloid leukemia (AML) from different levels. Our results showed that inhibiting TCTP expression could attenuate AML cells proliferation and induce apoptosis both in AML cell lines and in xenograft of NOD-SCID mice. In addition, either compared with patients in complete remission or non-leukemia patients, we detected that the expression of TCTP was generally high in the fresh bone marrow of AML patients, suggesting that there was a certain correlation between TCTP and AML disease progression. Taken together, our study revealed the role of TCTP in AML development, and provided a potential target for AML treatment.

Globally, nasopharyngeal carcinoma (NPC) is a prevalent and deadly malignancy. Despite the role of methyltransferase like 13 (METTL13) having been highlighted in a majority of human cancers, its function and mechanism in NPC is indistinct.
The expression level of METTL13 in NPC cell lines and normal cells was detected using a quantitative real-time polymerase chain reaction. Gain- and loss-of function experiments were conducted. Cell counting kit-8, 5-ethynyl-2\'-deoxyuridine, wound-healing, Transwell and tube formation assays, respectively, appraised the proliferative, migratory, invasive and angiogenic cellular responses. Corresponding protein expression was measured by western blotting. A chromatin immunoprecipitation assay was applied to verify the association between ZEB1 and the TPT1 promoter. Eventually, to substantiate the critical role of METTL13 in NPC, the establishment of an in vivo tumorigenesis model was accomplished.
METTL13 possessed fortified expression in NPC cells. METTL13 silencing markedly suppressed NPC cellular phenotypes in vitro, including proliferative, migratory, invasive and angiogenic events, as well as hindered tumorigenesis in vivo. Additionally, METTL13 positively regulated ZEB1, whereas ZEB1 could bind to TPT1 promoter and transcriptionally regulate TPT1. TPT1 was also found to be upregulated in NPC cells. TPT1 silencing suppressed NPC cellular phenotypes in vitro. TPT1 overexpression partly weakened the anti-tumor effect of METTL13 in NPC.
In summary, METTL13 up-regulated ZEB1, which facilitated the transcriptional activation of TPT1, ultimately promoting NPC growth and metastasis, providing a potential therapeutic strategy for NPC treatment.

Scabies is a common parasitic dermatological infection worldwide that is often neglected. Scabies mites stimulate host inflammatory symptoms via secreted and excreted proteins, which induce basophil and mast cell degranulation and host histamine release. However, the mechanism of degranulation and histamine release is unclear. Moreover, the Sarcoptes scabiei translationally controlled tumor protein (TCTP) is predicted as an excreted protein, which may be involved in host inflammatory response regulation. First, we evaluated S. scabiei TCTP gene (SsTCTP) transcription in larvae, nymphs, and adults by qRT-PCR, and SsTCTP transcription was highest in larvae, followed by nymphs. Second, we found that the S. scabiei TCTP recombinant protein (rSsTCTP) promoted mice histamine release in vivo by Evans blue Miles assay. Therefore, to further explore the possible role of S. scabiei TCTP in host inflammatory response regulation, we established a degranulation model of KU812 cells. The results of the degranulation model suggested that rSsTCTP could induce enhanced degranulation of KU812 cells and increase the secretion of histamine and the expression of IL-4, IL-6, and IL-13 in vitro. In conclusion, we speculate that scabies mites could stimulate host histamine release and Th2 response by excreting S. scabiei TCTP.

Translationally controlled tumor protein (TCTP) is a highly conserved multifunctional protein localized in the cytoplasm and nucleus of eukaryotic cells. It is secreted through exosomes and its degradation is associated with the ubiquitin-proteasome system (UPS), heat shock protein 27 (Hsp27), and chaperone-mediated autophagy (CMA). Its structure contains three α‍-helices and eleven β‍-strands, and features a helical hairpin as its hallmark. TCTP shows a remarkable similarity to the methionine-R-sulfoxide reductase B (MsrB) and mammalian suppressor of Sec4 (Mss4/Dss4) protein families, which exerts guanine nucleotide exchange factor (GEF) activity on small guanosine triphosphatase (GTPase) proteins, suggesting that some functions of TCTP may at least depend on its GEF action. Indeed, TCTP exerts GEF activity on Ras homolog enriched in brain (Rheb) to boost the growth and proliferation of Drosophila cells. TCTP also enhances the expression of cell division control protein 42 homolog (Cdc42) to promote cancer cell invasion and migration. Moreover, TCTP regulates cytoskeleton organization by interacting with actin microfilament (MF) and microtubule (MT) proteins and inducing the epithelial-mesenchymal transition (EMT) process. In essence, TCTP promotes cancer cell movement. It is usually highly expressed in cancerous tissues and thus reduces patient survival; meanwhile, drugs can target TCTP to reduce this effect. In this review, we summarize the mechanisms of TCTP in promoting cancer invasion and migration, and describe the current inhibitory strategy to target TCTP in cancerous diseases.

TPT1 Antisense RNA 1 (TPT1-AS1) is a recently identified tumor oncogenic long non-coding RNA (lncRNA) in ovarian cancer and cervical cancer. This study was carried out to study the role of lncRNA TPT1-AS1 in hepatocellular carcinoma (HCC). Samples of HCC and non-tumor tissues derived from 62 HCC patients were subjected to RNA isolation and reverse transcription quantitative polymerase chain reaction to detect the differential expression of TPT1-AS1 and cyclin dependent kinase 2 (CDK2) in HCC. Correlations between the expression of TPT1-AS1 and CDK2 were analyzed by linear regression. TPT1-AS1 and CDK2 were overexpressed in SNU-398 and SU.86.86 cells to explore their relationship. The role of TPT1-AS1 and CDK2 in regulating the cell cycle progression and proliferation of SNU-398 and SU.86.86 cells was explored by cell cycle assay and cell proliferation assay, respectively. In addition, xenograft tumor formation was also carried out to further verify the TPT1-AS1 role in HCC in vivo. It was found that TPT1-AS1 was downregulated in HCC and inversely correlated with CDK2. The expression of TPT1-AS1 in HCC tissues was not affected by age, sex, AFP, HBV, HCV, and cirrhosis infection but was downregulated by clinical stages. In HCC cells, overexpression of TPT1-AS1 mediated the downregulation of CDK2, while silencing of TPT1-AS1 mediated the upregulation of CDK2. In cell proliferation assay, overexpression of TPT1-AS1 mediated the decreased proliferation rates, while silencing of TPT1-AS1 mediated the increased proliferation rates of HCC cells, while overexpression of CDK2 played an opposite role. In addition, overexpression of TPT1-AS1 reduced tumor growth in vivo. Therefore, overexpression of TPT1-AS1 may suppress HCC cell proliferation by downregulating CDK2.

Objective: To investigate the effects of tumor protein translation control antisense RNA1 (TPT1-AS1) on the radiosensitivity, cell proliferation, migration and invasion of hepatocellular carcinoma cells by targeting microRNA-30c-5p (miR-30c-5p). Methods: Thirty-four cases of liver cancer tissues and adjacent normal tissues were derived from liver cancer patients who were admitted to Shanxi Provincial People\'s Hospital from March 2016 to March 2018. Liver cancer HepG2 cell was transfected with negative control siRNA (si-NC group), si-TPT1-AS1 (si-TPT1-AS1 group), pcDNA3.1 (pcDNA3.1 group), pcDNA3.1-TPT1-AS1 (pcDNA3.1-TPT1-AS1 group), si-TPT1-AS1 and anti-miR-NC (si-TPT1-AS1+ anti-miR-NC group), si-TPT1-AS1 and anti-miR-30c-5p (si-TPT1-AS1+ anti-miR-30c-5p group), respectively. Real-time quantitative reverse transcription polymerase chain reaction (qPCR) was used to detect the transcription levels of TPT1-AS1 and miR-30c-5p in normal tissues adjacent to cancer and liver cancer tissues, the clone formation test was used to test the radiosensitivity of HepG2 cells, and the Methyl Thiazolyl Tetrazolium (MTT) test was used to test the proliferation of HepG2 cells. Cell cycle distribution was detected by flow cytometry, Transwell array was used to detect the migration and invasion ability of HepG2 cells, dual luciferase reporter array was used to verify the targeting relationship of TPT1-AS1 and miR-30c-5p, western blot was used to detect the expressions of proliferation, migration and invasion-related proteins. Results: The expression levels of TPT1-AS1 and miR-30c-5p in liver cancer tissues were 0.84±0.08 and 0.13±0.01, statistically different from 0.31±0.03 and 0.50±0.05 in normal tissues adjacent to cancer (P<0.05). When the cells were treated with 2, 4, 6, 8 Gy irradiation, the cell survival scores of the si-TPT1-AS1 group were 0.280±0.040, 0.069±0.011, 0.020±0.003 and 0.005±0.001, respectively, lower than 0.648±0.070, 0.348±0.080, 0.130±0.020 and 0.060±0.009 of the si-NC group (P<0.05), the radiosensitization ratio of the si-TPT1-AS1 group was 1.672. The number of cell migration and invasion in the si-TPT1-AS1 group were (50.00±4.36) and (44.00±4.03), respectively, which were lower than (109.00±8.68) and (94.00±7.49) in the si-NC group (P<0.05), the cell absorbance (A) values at 24, 48 and 72 hours were 0.28±0.03, 0.43±0.04 and 0.68±0.07, respectively, lower than 0.46±0.04, 0.87±0.08 and 1.35±0.13 of the si-NC group (P<0.05), the protein expression levels of Cyclin D1, p21, E-cadherin and MMP-2 were 0.25±0.02, 0.65±0.06, 0.68±0.07 and 0.27±0.03, respectively, statistically different from 0.88±0.08, 0.17±0.02, 0.14±0.01 and 0.89±0.09 of si-NC group (P<0.05), the proportions of S phase and G(2) phase in the si-TPT1-AS1 group were (17.82±1.03)% and (34.15±2.29)%, respectively, significantly different from (35.14±2.61)% and (16.84±1.21)% in the si-NC group (P<0.05). The luciferase activity of cells in the WT-TPT1-AS1+ miR-30c-5p group was 0.26±0.02, lower than 0.92±0.09 in the WT-TPT1-AS1+ miR-NC group (P<0.05). The cell survival scores in the si-TPT1-AS1+ anti-miR-30c-5p group were 0.450±0.081, 0.200+ 0.045, 0.070±0.010, 0.026±0.004 after treatment with 2, 4, 6, 8 Gy irradiation, higher than 0.285±0.043, 0.075±0.014, 0.028±0.004, 0.006±0.001 of si-TPT1-AS1+ anti-miR-NC group (P<0.05). The radiosensitization ratio of the si-TPT1-AS1+ anti-miR-30c-5p group was 0.694. The number of migration and invasion in the si-TPT1-AS1+ anti-miR-30c-5p group were 79.00±6.65 and 68.00±6.33, higher than (52.00±4.41) and (46.00±4.06) of si-TPT1-AS1+ anti-miR-NC Group (P<0.05), the A values at 24, 48 and 72 hours were 0.37±0.03, 0.64±0.06 and 0.96±0.09, respectively, higher than 0.26±0.03, 0.41±0.04, and 0.65±0.06 of si-TPT1-AS1+ anti-miR-NC group (P<0.05), the expression levels of Cyclin D1, p21, E-cadherin and MMP-2 protein were 0.57±0.06, 0.43±0.04, 0.43±0.04 and 0.64±0.06, statistically different from 0.24±0.02, 0.66±0.06, 0.65±0.06 and 0.28±0.03 of the si-TPT1-AS1+ anti-miR-NC group (P<0.05). Conclusions: The expression of TPT1-AS1 up-regulates in the liver cancer tissues. TPT1-AS1 may down-regulate miR-30c-5p expression, reduce the radiosensitivity of liver cancer cells, and promote the proliferation, migration and invasion of liver cancer cells.
目的： 探讨肿瘤蛋白翻译控制反义RNA1(TPT1-AS1)靶向miR-30c-5p对肝癌细胞放射敏感性、细胞增殖、迁移和侵袭的影响。 方法： 34例肝癌组织及癌旁正常组织来源于2016年3月至2018年3月就诊于山西省人民医院的肝癌患者。将肝癌HepG2细胞分为si-NC组(转染si-NC)、si-TPT1-AS1组(转染si-TPT1-AS1)、pcDNA3.1组(转染pcDNA3.1)、pcDNA3.1-TPT1-AS1组(转染pcDNA3.1-TPT1-AS1)、si-TPT1-AS1+anti-miR-NC组(转染si-TPT1-AS1和anti-miR-NC)、si-TPT1-AS1+anti-miR-30c-5p组(转染si-TPT1-AS1+anti-miR-30c-5p)。采用实时荧光定量聚合酶链反应检测癌旁正常组织和肝癌组织中TPT1-AS1和miR-30c-5p的基因表达，克隆形成实验检测细胞放射敏感性，MTT实验检测细胞增殖活力，流式细胞数检测细胞周期分布，Transwell实验检测细胞迁移和侵袭能力，双荧光素酶报告基因实验验证TPT1-AS1和miR-30c-5p的靶向关系，Western blot检测增殖、迁移和侵袭相关蛋白的表达。 结果： 肝癌组织中TPT1-AS1和miR-30c-5p的表达水平为0.84±0.08和0.13±0.01，与癌旁正常组织(分别为0.31±0.03和0.50±0.05)比较，差异均有统计学意义(均P<0.05)。采用2、4、6、8 Gy照射细胞时，si-TPT1-AS1组细胞存活分数分别为0.280±0.040、0.069±0.011、0.020±0.003和0.005±0.001，均低于si-NC组(分别为0.648±0.070、0.348±0.080、0.130±0.020和0.060±0.009，均P<0.05)，si-TPT1-AS1组细胞放射增敏比为1.672。si-TPT1-AS1组细胞迁移数、侵袭数分别为(50.00±4.36)个和(44.00±4.03)个，低于si-NC组[分别为(109.00±8.68)个和(94.00±7.49)个，均P<0.05]。培养24、48和72 h，si-TPT1-AS1组细胞吸光度(A)值分别为0.28±0.03、0.43±0.04和0.68±0.07，低于si-NC组(分别为0.46±0.04、0.87±0.08和1.35±0.13，均P<0.05)。si-TPT1-AS1组细胞周期素D1(Cyclin D1)、p21、E-cadherin和基质金属蛋白酶2(MMP-2)蛋白表达水平分别为0.25±0.02、0.65±0.06、0.68±0.07和0.27±0.03，与si-NC组(分别为0.88±0.08、0.17±0.02、0.14±0.01和0.89±0.09)比较，差异均有统计学意义(均P<0.05)。si-TPT1-AS1组细胞S期和G(2)期细胞比例分别为(17.82±1.03)%和(34.15±2.29)%，与si-NC组[(35.14±2.61)%和(16.84±1.21)%]比较，差异均有统计学意义(均P<0.05)。WT-TPT1-AS1+miR-30c-5p组细胞荧光素酶活性为0.26±0.02，低于WT-TPT1-AS1+miR-NC组(0.92±0.09，P<0.05)。照射2、4、6、8 Gy，si-TPT1-AS1+anti-miR-30c-5p组细胞存活分数分别为0.450±0.081、0.200+0.045、0.070±0.010、0.026±0.004，高于si-TPT1-AS1+anti-miR-NC组(分别为0.285±0.043、0.075±0.014、0.028±0.004、0.006±0.001，均P<0.05)。si-TPT1-AS1+anti-miR-30c-5p组细胞放射增敏比为0.694。si-TPT1-AS1+anti-miR-30c-5p组细胞迁移数、侵袭数分别为(79.00±6.65)个和(68.00±6.33)个，高于si-TPT1-AS1+anti-miR-NC组[分别为(52.00±4.41)个和(46.00±4.06)个，均P<0.05]。培养24、48和72 h，si-TPT1-AS1+anti-miR-30c-5p组细胞A值分别为0.37±0.03、0.64±0.06和0.96±0.09，高于si-TPT1-AS1+anti-miR-NC组[分别为0.26±0.03、0.41±0.04和0.65±0.06，均P<0.05]。si-TPT1-AS1+anti-miR-30c-5p组Cyclin D1、p21、E-cadherin和MMP-2蛋白的表达水平分别为0.57±0.06、0.43±0.04、0.43±0.04和0.64±0.06，与si-TPT1-AS1+anti-miR-NC组(分别为0.24±0.02、0.66±0.06、0.65±0.06和0.28±0.03)比较，差异均有统计学意义(均P<0.05)。 结论： TPT1-AS1在肝癌组织中表达上调，TPT1-AS1可能通过靶向下调miR-30c-5p的表达，降低肝癌细胞的放射敏感性，促进肝癌细胞的增殖、迁移和侵袭。.

暂无摘要。

Long non-coding RNAs (lncRNAs) are key modulators during cancer progression. Application of using lncRNA expression to evaluate patient prognosis and sensitivity to treatment is highly anticipated, yet the expression and mechanism of many lncRNAs remain unknown. Herein, we projected for the investigation of TPT1-AS1 function in breast cancer. TPT1-AS1 was assessed by bioinformatic analysis of publicly available datasets and quantitative real-time PCR (qRT-PCR). Cell sensitivity to paclitaxel and cell proliferation was measured by flow cytometry and CCK-8. Interaction among TPT1-AS1, microRNA (miRNA, miR)-3156-5p and Caspase 2 (CASP2) was studied by bioinformatic analysis, qRT-PCR, western blot as well as dual luciferase reporter assay. Herein, TPT1-AS1 was significantly diminished in breast cancer from publicly available datasets and our collected samples. In breast cancer cells, TPT1-AS1 overexpression repressed cell proliferation and sensitized breast cancer cells to paclitaxel. RegRNA 2.0 predicted a potential interaction between TPT1-AS1 and miR-3156-5p which was confirmed by qRT-PCR as well as dual luciferase reporter assay. CASP2, a proapoptotic gene, was corroborated to be targeted by miR-3156-5p. Meanwhile, TPT1-AS1 upregulated CASP2 in breast cancer cells, and its biological function was reversed by CASP2 knockdown. Collectively, TPT1-AS1 diminished cell proliferation and sensitized cells to chemotherapy by sponging miR-3156-5p and upregulating CASP2, acting as a biomarker for patients with breast cancer.