Your search keyword '"Qianghu Wang"' showing total 6 results

1. PDPN marks a subset of aggressive and radiation-resistant glioblastoma cells

Author

Aram S. Modrek, Eskil Eskilsson, Ravesanker Ezhilarasan, Qianghu Wang, Lindsey D. Goodman, Yingwen Ding, Ze-Yan Zhang, Krishna P. L. Bhat, Thanh-Thuy T. Le, Floris P. Barthel, Ming Tang, Jie Yang, Lihong Long, Joy Gumin, Frederick F. Lang, Roel G. W. Verhaak, Kenneth D. Aldape, and Erik P. Sulman

Subjects

glioma, glioblastoma, PDPN, podoplanin, CD133, radioresistance, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Treatment-resistant glioma stem cells are thought to propagate and drive growth of malignant gliomas, but their markers and our ability to target them specifically are not well understood. We demonstrate that podoplanin (PDPN) expression is an independent prognostic marker in gliomas across multiple independent patient cohorts comprising both high- and low-grade gliomas. Knockdown of PDPN radiosensitized glioma cell lines and glioma-stem-like cells (GSCs). Clonogenic assays and xenograft experiments revealed that PDPN expression was associated with radiotherapy resistance and tumor aggressiveness. We further demonstrate that knockdown of PDPN in GSCs in vivo is sufficient to improve overall survival in an intracranial xenograft mouse model. PDPN therefore identifies a subset of aggressive, treatment-resistant glioma cells responsible for radiation resistance and may serve as a novel therapeutic target.

Published

2022

2. Detection and Localization of Solid Tumors Utilizing the Cancer-Type-Specific Mutational Signatures

Author

Ziyu Wang, Tingting Zhang, Wei Wu, Lingxiang Wu, Jie Li, Bin Huang, Yuan Liang, Yan Li, Pengping Li, Kening Li, Wei Wang, Renhua Guo, and Qianghu Wang

Subjects

cancer biomarkers, cancer diagnosis, cancer localization, mutational signatures, liquid biopsy, Biotechnology, TP248.13-248.65

Abstract

Accurate detection and location of tumor lesions are essential for improving the diagnosis and personalized cancer therapy. However, the diagnosis of lesions with fuzzy histology is mainly dependent on experiences and with low accuracy and efficiency. Here, we developed a logistic regression model based on mutational signatures (MS) for each cancer type to trace the tumor origin. We observed MS could distinguish cancer from inflammation and healthy individuals. By collecting extensive datasets of samples from ten tumor types in the training cohort (5,001 samples) and independent testing cohort (2,580 samples), cancer-type-specific MS patterns (CTS-MS) were identified and had a robust performance in distinguishing different types of primary and metastatic solid tumors (AUC:0.76 ∼ 0.93). Moreover, we validated our model in an Asian population and found that the AUC of our model in predicting the tumor origin of the Asian population was higher than 0.7. The metastatic tumor lesions inherited the MS pattern of the primary tumor, suggesting the capability of MS in identifying the tissue-of-origin for metastatic cancers. Furthermore, we distinguished breast cancer and prostate cancer with 90% accuracy by combining somatic mutations and CTS-MS from cfDNA, indicating that the CTS-MS could improve the accuracy of cancer-type prediction by cfDNA. In summary, our study demonstrated that MS was a novel reliable biomarker for diagnosing solid tumors and provided new insights into predicting tissue-of-origin.

Published

2022

3. Laboratory Testing Implications of Risk-Stratification and Management of COVID-19 Patients

Author

Caidong Liu, Ziyu Wang, Wei Wu, Changgang Xiang, Lingxiang Wu, Jie Li, Weiye Hou, Huiling Sun, Youli Wang, Zhenling Nie, Yingdong Gao, Ruisheng Zhang, Haixia Tang, Qianghu Wang, Kening Li, Xinyi Xia, Pengping Li, and Shukui Wang

Subjects

COVID-19, laboratory testing, diagnosis, monitoring, prediction model, Medicine (General), R5-920

Abstract

Objective: To distinguish COVID-19 patients and non-COVID-19 viral pneumonia patients and classify COVID-19 patients into low-risk and high-risk at admission by laboratory indicators.Materials and methods: In this retrospective cohort, a total of 3,563 COVID-19 patients and 118 non-COVID-19 pneumonia patients were included. There are two cohorts of COVID-19 patients, including 548 patients in the training dataset, and 3,015 patients in the testing dataset. Laboratory indicators were measured during hospitalization for all patients. Based on laboratory indicators, we used the support vector machine and joint random sampling to risk stratification for COVID-19 patients at admission. Based on laboratory indicators detected within the 1st week after admission, we used logistic regression and joint random sampling to develop the survival mode. The laboratory indicators of COVID-10 and non-COVID-19 were also compared.Results: We first identified the significant laboratory indicators related to the severity of COVID-19 in the training dataset. Neutrophils percentage, lymphocytes percentage, creatinine, and blood urea nitrogen with AUC >0.7 were included in the model. These indicators were further used to build a support vector machine model to classify patients into low-risk and high-risk at admission in the testing dataset. Results showed that this model could stratify the patients in the testing dataset effectively (AUC = 0.89). Our model still has good performance at different times (Mean AUC: 0.71, 0.72, 0.72, respectively for 3, 5, and 7 days after admission). Moreover, laboratory indicators detected within the 1st week after admission were able to estimate the probability of death (AUC = 0.95). We identified six indicators with permutation p < 0.05, including eosinophil percentage (p = 0.007), white blood cell count (p = 0.045), albumin (p = 0.041), aspartate transaminase (p = 0.043), lactate dehydrogenase (p = 0.002), and hemoglobin (p = 0.031). We could diagnose COVID-19 and differentiate it from other kinds of viral pneumonia based on these laboratory indicators.Conclusions: Our risk-stratification model based on laboratory indicators could help to diagnose, monitor, and predict severity at an early stage of COVID-19. In addition, laboratory findings could be used to distinguish COVID-19 and non-COVID-19.

Published

2021

4. Comparative Characterization and Risk Stratification of Asymptomatic and Presymptomatic Patients With COVID-19

Author

Lei Shi, Rong Ding, Tingting Zhang, Wei Wu, Ziyu Wang, Xiuzhi Jia, Kening Li, Yuan Liang, Jie Li, Mengyan Zhu, Bin Huang, Lingxiang Wu, Min Wu, Jing Chen, Chaochen Wang, Caidong Liu, Hongbing Shen, Qianghu Wang, Xinyi Xia, Pengping Li, Sali Lyu, and Ying Xiao

Subjects

risk stratification, COVID-19, asymptomatic patients, presymptomatic patients, T cell exhaustion, Immunologic diseases. Allergy, RC581-607

Abstract

The identification of asymptomatic, non-severe presymptomatic, and severe presymptomatic coronavirus disease 2019 (COVID-19) in patients may help optimize risk-stratified clinical management and improve prognosis. This single-center case series from Wuhan Huoshenshan Hospital, China, included 2,980 patients with COVID-19 who were hospitalized between February 4, 2020 and April 10, 2020. Patients were diagnosed as asymptomatic (n = 39), presymptomatic (n = 34), and symptomatic (n = 2,907) upon admission. This study provided an overview of asymptomatic, presymptomatic, and symptomatic COVID-19 patients, including detection, demographics, clinical characteristics, and outcomes. Upon admission, there was no significant difference in clinical symptoms and CT image between asymptomatic and presymptomatic patients for diagnosis reference. The mean area under the receiver operating characteristic curve (AUC) of the differential diagnosis model to discriminate presymptomatic patients from asymptomatic patients was 0.89 (95% CI, 0.81-0.98). Importantly, the severe and non-severe presymptomatic patients can be further stratified (AUC = 0.82). In conclusion, the two-step risk-stratification model based on 10 laboratory indicators can distinguish among asymptomatic, severe presymptomatic, and non-severe presymptomatic COVID-19 patients on admission. Moreover, single-cell data analyses revealed that the CD8+T cell exhaustion correlated to the progression of COVID-19.

Published

2021

5. High Expression of ACE2 and TMPRSS2 at the Resection Margin Makes Lung Cancer Survivors Susceptible to SARS-CoV-2 With Unfavorable Prognosis

Author

Qianqian Wang, Liangyu Li, Tianyu Qu, Jie Li, Lingxiang Wu, Kening Li, Ziyu Wang, Mengyan Zhu, Bin Huang, Wei Wu, Min Wu, Rong Ding, Zhihong Zhang, Qianghu Wang, Xinyi Xia, Pengping Li, Zhi Zhang, and Renhua Guo

Subjects

COVID-19, lung cancer, ACE2, single cell, tmprss2, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

BackgroundCoronavirus disease 2019 (COVID-19) has rapidly spread worldwide. Systematic analysis of lung cancer survivors at molecular and clinical levels is warranted to understand the disease course and clinical characteristics.MethodsA single-center, retrospective cohort study was conducted in 65 patients with COVID-19 from Wuhan Huoshenshan Hospital, of which 13 patients were diagnosed with lung cancer. The study was conducted from February 4 to April 11, 2020.ResultsDuring the course of treatment, lung cancer survivors infected with severe acute respiratory syndrome coronavirus 2 (SARS-COV-2) had shorter median time from symptom onset to hospitalization (P = 0.016) and longer clinical symptom remission time (P = 0.020) than non-cancer individuals. No differences were observed among indicators such as time from symptom onset to hospitalization and symptom remission time between medium-term and short-term survivors. The expression of ACE2 (P = 0.013) and TMPRSS2 (P

Published

2021

6. PDPN marks a subset of aggressive and radiationresistant glioblastoma cells.

Author

Modrek, Aram S., Eskilsson, Eskil, Ezhilarasan, Ravesanker, Qianghu Wang, Goodman, Lindsey D., Yingwen Ding, Ze-Yan Zhang, Bhat, Krishna P. L., Le, Thanh-Thuy T., Barthel, Floris P., Ming Tang, Jie Yang, Lihong Long, Gumin, Joy, Lang, Frederick F., Verhaak, Roel G. W., Aldape, Kenneth D., and Sulman, Erik P.

Subjects

GLIOBLASTOMA multiforme, PROGNOSIS, GLIOMAS, CELL lines, OVERALL survival

Abstract

Treatment-resistant glioma stem cells are thought to propagate and drive growth of malignant gliomas, but their markers and our ability to target them specifically are not well understood. We demonstrate that podoplanin (PDPN) expression is an independent prognostic marker in gliomas across multiple independent patient cohorts comprising both high- and low-grade gliomas. Knockdown of PDPN radiosensitized glioma cell lines and glioma-stem-like cells (GSCs). Clonogenic assays and xenograft experiments revealed that PDPN expression was associated with radiotherapy resistance and tumor aggressiveness. We further demonstrate that knockdown of PDPN in GSCs in vivo is sufficient to improve overall survival in an intracranial xenograft mouse model. PDPN therefore identifies a subset of aggressive, treatment-resistant glioma cells responsible for radiation resistance and may serve as a novel therapeutic target. [ABSTRACT FROM AUTHOR]

Published

2022