Your search keyword '"Melissa P. Pizzi"' showing total 12 results

1. METI: deep profiling of tumor ecosystems by integrating cell morphology and spatial transcriptomics

Author

Jiahui Jiang, Yunhe Liu, Jiangjiang Qin, Jianfeng Chen, Jingjing Wu, Melissa P. Pizzi, Rossana Lazcano, Kohei Yamashita, Zhiyuan Xu, Guangsheng Pei, Kyung Serk Cho, Yanshuo Chu, Ansam Sinjab, Fuduan Peng, Xinmiao Yan, Guangchun Han, Ruiping Wang, Enyu Dai, Yibo Dai, Bogdan A. Czerniak, Andrew Futreal, Anirban Maitra, Alexander Lazar, Humam Kadara, Amir A. Jazaeri, Xiangdong Cheng, Jaffer Ajani, Jianjun Gao, Jian Hu, and Linghua Wang

Subjects

Science

Abstract

Abstract Recent advances in spatial transcriptomics (ST) techniques provide valuable insights into cellular interactions within the tumor microenvironment (TME). However, most analytical tools lack consideration of histological features and rely on matched single-cell RNA sequencing data, limiting their effectiveness in TME studies. To address this, we introduce the Morphology-Enhanced Spatial Transcriptome Analysis Integrator (METI), an end-to-end framework that maps cancer cells and TME components, stratifies cell types and states, and analyzes cell co-localization. By integrating spatial transcriptomics, cell morphology, and curated gene signatures, METI enhances our understanding of the molecular landscape and cellular interactions within the tissue. We evaluate the performance of METI on ST data generated from various tumor tissues, including gastric, lung, and bladder cancers, as well as premalignant tissues. We also conduct a quantitative comparison of METI with existing clustering and cell deconvolution tools, demonstrating METI’s robust and consistent performance.

Published

2024

2. Proteogenomic landscape of gastric adenocarcinoma peritoneal metastases

Author

Shuangtao Zhao, Ruiping Wang, Shumei Song, Dapeng Hao, Guangchun Han, Xingzhi Song, Jianhua Zhang, Melissa Pool Pizzi, Namita Shanbhag, Andrew Futreal, Brian Badgwell, Kazuto Harada, George Calin, Jody Vykoukal, Chuan-Yih Yu, Hiroyuki Katayama, Samir M. Hanash, Linghua Wang, and Jaffer A. Ajani

Subjects

Biological sciences, Cancer, Genomics, Proteomics, Science

Abstract

Summary: Advanced gastric adenocarcinoma (GAC) often leads to peritoneal carcinomatosis (PC) and is associated with very poor outcome. Here we report the comprehensive proteogenomic study of ascites derived cells from a prospective GAC cohort (n = 26 patients with peritoneal carcinomatosis, PC). A total of 16,449 proteins were detected from whole cell extracts (TCEs). Unsupervised hierarchical clustering resulted in three distinct groups that reflected extent of enrichment in tumor cells. Integrated analysis revealed enriched biological pathways and notably, some druggable targets (cancer-testis antigens, kinases, and receptors) that could be exploited to develop effective therapies and/or tumor stratifications. Systematic comparison of expression levels of proteins and mRNAs revealed special expression patterns of key therapeutics target notably high mRNA and low protein expression of HAVCR2 (TIM-3), and low mRNA but high protein expression of cancer-testis antigens CTAGE1 and CTNNA2. These results inform strategies to target GAC vulnerabilities.

Published

2023

3. GRK3 is a poor prognosticator and serves as a therapeutic target in advanced gastric adenocarcinoma

Author

Yuan Li, Yibo Fan, Jinbang Xu, Longfei Huo, Ailing W. Scott, Jiankang Jin, Boxuan Yang, Shan Shao, Lang Ma, Ying Wang, Xiaodan Yao, Melissa Pool Pizzi, Matheus Sewastjanow Da Silva, Guoliang Zhang, Lijuan Zhuo, Eun Jeong Cho, Kevin N. Dalby, Namita D. Shanbhag, Zhenning Wang, Wenliang Li, Shumei Song, and Jaffer A. Ajani

Subjects

Gastric adenocarcinoma, GRK3, Hippo/YAP1, Prognosis, Peritoneal metastases, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background G protein-coupled receptor (GPCR) is the most targeted protein family by the FDA-approved drugs. GPCR-kinase 3 (GRK3) is critical for GPCR signaling. Our genomic analysis showed that GRK3 expression correlated with poor prognosis of gastric adenocarcinoma (GAC) patients. However, GRK3’s functions and clinical utility in GAC progression and metastases are unknown. Methods We studied GRK3 expression in normal, primary, and metastatic GAC tissues. We identified a novel GRK3 inhibitor, LD2, through a chemical-library screen. Through genetic and pharmacologic modulations of GRK3, a series of functional and molecular studies were performed in vitro and in vivo. Impact of GRK3 on YAP1 and its targets was determined. Results GRK3 was overexpressed in GAC tissues compared to normal and was even higher in peritoneal metastases. Overexpression (OE) of GRK3 was significantly associated with shorter survival. Upregulation of GRK3 in GAC cells increased cell invasion, colony formation, and proportion of ALDH1 + cells, while its downregulation reduced these attributes. Further, LD2 potently and specifically inhibited GRK3, but not GRK2, a very similar kinase to GRK3. LD2 highly suppressed GAC cells’ malignant phenotypes in vitro. Mechanistically, GRK3 upregulated YAP1 in GAC tissues and its transcriptional downstream targets: SOX9, Birc5, Cyr61 and CTGF. Knockdown (KD) YAP1 rescued the phenotypes of GRK3 OE in GAC cells. GRK3 OE significantly increased tumor growth but LD2 inhibited tumor growth in the PDX model and dramatically suppressed peritoneal metastases induced by GRK3 OE. Conclusions GRK3, a poor prognosticator for survival, conferred aggressive phenotype. Genetic silencing of GRK3 or its inhibitor LD2 blunted GRK3-conferred malignant attributes, suggesting GRK3 as a novel therapeutic target in advanced GAC.

Published

2022

4. A new intronic quantitative PCR method led to the discovery of transformation from human ascites to murine malignancy in a mouse model

Author

Jiankang Jin, Longfei Huo, Yibo Fan, Ruiping Wang, Ailing W. Scott, Melissa Pool Pizzi, Xiaodan Yao, Shan Shao, Lang Ma, Matheus S. Da Silva, Kohei Yamashita, Katsuhiro Yoshimura, Boyu Zhang, Jingjing Wu, Linghua Wang, Shumei Song, and Jaffer A. Ajani

Subjects

intronic genomic qPCR, authentication and quantification of human and murine samples, patient-derived xenograft (PDX), human-to-murine oncogenic transformation, whole exosome sequencing (WES), tumor microenvironment (TME), Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

PurposeTo establish a fast and accurate detection method for interspecies contaminations in the patient-derived xenograft (PDX) models and cell lines, and to elucidate possible mechanisms if interspecies oncogenic transformation is detected.MethodsA fast and highly sensitive intronic qPCR method detecting Gapdh intronic genomic copies was developed to quantify if cells were human or murine or a mixture. By this method, we documented that murine stromal cells were abundant in the PDXs; we also authenticated our cell lines to be human or murine.ResultsIn one mouse model, GA0825-PDX transformed murine stromal cells into a malignant tumorigenic murine P0825 cell line. We traced the timeline of this transformation and discovered three subpopulations descended from the same GA0825-PDX model: epithelium-like human H0825, fibroblast-like murine M0825, and main passaged murine P0825 displayed differences in tumorigenic capability in vivo. P0825 was the most aggressive and H0825 was weakly tumorigenic. Immunofluorescence (IF) staining revealed that P0825 cells highly expressed several oncogenic and cancer stem cell markers. Whole exosome sequencing (WES) analysis revealed that TP53 mutation in the human ascites IP116-generated GA0825-PDX may have played a role in the human-to-murine oncogenic transformation.ConclusionThis intronic qPCR is able to quantify human/mouse genomic copies with high sensitivity and within a time frame of a few hours. We are the first to use intronic genomic qPCR for authentication and quantification of biosamples. Human ascites transformed murine stroma into malignancy in a PDX model.

Published

2023

5. Patient-derived cell lines and orthotopic mouse model of peritoneal carcinomatosis recapitulate molecular and phenotypic features of human gastric adenocarcinoma

Author

Shumei Song, Yan Xu, Longfei Huo, Shuangtao Zhao, Ruiping Wang, Yuan Li, Ailing W. Scott, Melissa Pool Pizzi, Ying Wang, Yibo Fan, Kazuto Harada, Jiankang Jin, Lang Ma, Xiaodan Yao, Namita D. Shanbhag, Qiong Gan, Sinchita Roy-Chowdhuri, Brian D. Badgwell, Zhenning Wang, Linghua Wang, and Jaffer A. Ajani

Subjects

Gastric adenocarcinoma, Peritoneal metastases, Patient-derived cell lines, Patient-derived xenograft, molecular profile, Patient-derived orthotopic model, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background Gastric adenocarcinoma with peritoneal carcinomatosis (PC) is therapy resistant and leads to poor survival. To study PC in depth, there is an urgent need to develop representative PC-derived cell lines and metastatic models to study molecular mechanisms of PC and for preclinical screening of new therapies. Methods PC cell lines were developed from patient-derived PC cells. The tumorigenicity and metastatic potential were investigated by subcutaneously (PDXs) and orthotopically. Karyotyping, whole-exome sequencing, RNA-sequencing, and functional studies were performed to molecularly define the cell lines and compare genomic and phenotypic features of PDX and donor PC cells. Results We established three PC cell lines (GA0518, GA0804, and GA0825) and characterized them in vitro. The doubling times were 22, 39, and 37 h for GA0518, GA0804, and GA0825, respectively. Expression of cancer stem cell markers (CD44, ALDH1, CD133 and YAP1) and activation of oncogenes varied among the cell lines. All three PC cell lines formed PDXs. Interestingly, all three PC cell lines formed tumors in the patient derived orthotopic (PDO) model and GA0518 cell line consistently produced PC in mice. Moreover, PDXs recapitulated transcriptomic and phenotypic features of the donor PC cells. Finally, these cell lines were suitable for preclinical testing of chemotherapy and target agents in vitro and in vivo. Conclusion We successfully established three patient-derived PC cell lines and an improved PDO model with high incidence of PC associated with malignant ascites. Thus, these cell lines and metastatic PDO model represent excellent resources for exploring metastatic mechanisms of PC in depth and for target drug screening and validation by interrogating GAC for translational studies.

Published

2021

6. Targeting Hippo coactivator YAP1 through BET bromodomain inhibition in esophageal adenocarcinoma

Author

Shumei Song, Yuan Li, Yan Xu, Lang Ma, Melissa Pool Pizzi, Jiankang Jin, Ailing W Scott, Longfei Huo, Ying Wang, Jeffrey H. Lee, Manoop S. Bhutani, Brian Weston, Namita D Shanbhag, Randy L. Johnson, and Jaffer A. Ajani

Subjects

BRD4, CSCs, esophageal cancer, Hippo/YAP1, JQ1, therapy resistance, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Hippo/YAP1 signaling is a major regulator of organ size, cancer stemness, and aggressive phenotype. Thus, targeting YAP1 may provide a novel therapeutic strategy for tumors with high YAP1 expression in esophageal cancer (EC). Chromatin immunoprecipitation (ChiP) and quantitative ChiP‐PCR were used to determine the regulation of the chromatin remodeling protein bromodomain‐containing protein 4 (BRD4) on YAP1. The role of the bromodomain and extraterminal motif (BET) inhibitor JQ1, an established BRD4 inhibitor, on inhibition of YAP1 in EC cells was dissected using western blot, immunofluorescence, qPCR, and transient transfection. The antitumor activities of BET inhibitor were further examined by variety of functional assays, cell proliferation (MTS), tumorsphere, and ALDH1+ labeling in vitro and in vivo. Here, we show that BRD4 regulates YAP1 expression and transcription. ChiP assays revealed that BRD4 directly occupies YAP1 promoter and that JQ1 robustly blocks BRD4 binding to the YAP1 promoter. Consequently, JQ1 strongly suppresses constitutive or induced YAP1 expression and transcription in EC cells and YAP1/Tead downstream transcriptional activity. Intriguingly, radiation‐resistant cells that acquire strong cancer stem cell traits and an aggressive phenotype can be effectively suppressed by JQ1 as assessed by cell proliferation, tumorsphere formation, and reduction in the ALDH1+ cells. Moreover, effects of JQ1 are synergistically amplified by the addition of docetaxel in vitro and in vivo. Our results demonstrate that BRD4 is a critical regulator of Hippo/YAP1 signaling and that BRD4 inhibitor JQ1 represents a new class of inhibitor of Hippo/YAP1 signaling, primarily targeting YAP1 high and therapy‐resistant cancer cells enriched with cancer stem cell properties.

Published

2020

7. LncRNA PVT1 up-regulation is a poor prognosticator and serves as a therapeutic target in esophageal adenocarcinoma

Author

Yan Xu, Yuan Li, Jiankang Jin, Guangchun Han, Chengcao Sun, Melissa Pool Pizzi, Longfei Huo, Ailing Scott, Ying Wang, Lang Ma, Jeffrey H. Lee, Manoop S. Bhutani, Brian Weston, Christopher Vellano, Liuqing Yang, Chunru Lin, Youngsoo Kim, A. Robert MacLeod, Linghua Wang, Zhenning Wang, Shumei Song, and Jaffer A. Ajani

Subjects

Lnc RNA, PVT1, YAP1, Antisense oligonucleotides, Esophageal adenocarcinoma, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background PVT1 has emerged as an oncogene in many tumor types. However, its role in Barrett’s esophagus (BE) and esophageal adenocarcinoma (EAC) is unknown. The aim of this study was to assess the role of PVT1 in BE/EAC progression and uncover its therapeutic value against EAC. Methods PVT1 expression was assessed by qPCR in normal, BE, and EAC tissues and statistical analysis was performed to determine the association of PVT1 expression and EAC (stage, metastases, and survival). PVT1 antisense oligonucleotides (ASOs) were tested for their antitumor activity in vitro and in vivo. Results PVT1 expression was up-regulated in EACs compared with paired BEs, and normal esophageal tissues. High expression of PVT1 was associated with poor differentiation, lymph node metastases, and shorter survival. Effective knockdown of PVT1 in EAC cells using PVT1 ASOs resulted in decreased cell proliferation, invasion, colony formation, tumor sphere formation, and reduced proportion of ALDH1A1+ cells. Mechanistically, we discovered mutual regulation of PVT1 and YAP1 in EAC cells. Inhibition of PVT1 by PVT1 ASOs suppressed YAP1 expression through increased phosphor-LATS1and phosphor-YAP1 while knockout of YAP1 in EAC cells significantly suppressed PVT1 levels indicating a positive regulation of PVT1 by YAP1. Most importantly, we found that targeting both PVT1 and YAP1 using their specific ASOs led to better antitumor activity in vitro and in vivo. Conclusions Our results provide strong evidence that PVT1 confers an aggressive phenotype to EAC and is a poor prognosticator. Combined targeting of PVT1 and YAP1 provided the highest therapeutic index and represents a novel therapeutic strategy.

Published

2019

8. An improved strategy for CRISPR/Cas9 gene knockout and subsequent wildtype and mutant gene rescue.

Author

Jiankang Jin, Yan Xu, Longfei Huo, Lang Ma, Ailing W Scott, Melissa Pool Pizzi, Yuan Li, Ying Wang, Xiaodan Yao, Shumei Song, and Jaffer A Ajani

Subjects

Medicine, Science

Abstract

A fluorescence marker mOrange was inserted to the popular pLentiCrispr-V2 to create pLentiCrispr-V2-mOrange (V2mO) that contained both a puromycin selection and a fluorescent marker, making viral production and target transduction visible. Lentiviruses packaged with this plasmid and appropriate guide RNAs (gRNAs) successfully knocked out the genes RhoA, Gli1, and Gal3 in human gastric cancer cell lines. Cas9-gRNA editing efficiency could be estimated directly from Sanger electropherograms of short polymerase chain reaction products around the gRNA regions in Cas9-gRNA transduced cells. Single cloning of transduced target cell pools must be performed to establish stable knockout clones. Rescue of wildtype (RhoA and Gal3) and mutant (RhoA.Y42C) genes into knockout cells was successful only when cDNAs, where gRNAs bind, were modified by three nucleotides while the amino acid sequences remained unchanged. Stringent on-target CRISPR/Cas9 editing was observed in Gal3 gene, but not in RhoA gene since RhoA.Y42C already presented a nucleotide change in gRNA5 binding site. In summary, our improved strategy added these advantages: adding visual marker to the popular lentiviral system, monitoring lentiviral production and transduction efficiencies, cell-sorting Cas9+ cells in target cells by fluorescence-activated cell sorting, direct estimation of gene editing efficiency of target cell pools by short PCR electropherograms around gRNA binding sites, and successful rescue of wildtype and mutant genes in knockout cells, overcoming Cas9 editing by modifying cDNAs.

Published

2020

9. Correction to: LncRNA PVT1 up-regulation is a poor prognosticator and serves as a therapeutic target in esophageal adenocarcinoma

Author

Yan Xu, Yuan Li, Jiankang Jin, Guangchun Han, Chengcao Sun, Melissa Pool Pizzi, Longfei Huo, Ailing Scott, Ying Wang, Lang Ma, Jeffrey H. Lee, Manoop S. Bhutani, Brian Weston, Christopher Vellano, Liuqing Yang, Chunru Lin, Youngsoo Kim, A. Robert MacLeod, Linghua Wang, Zhenning Wang, Shumei Song, and Jaffer A. Ajani

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

An amendment to this paper has been published and can be accessed via the original article.

Published

2021

10. Pan-cancer T cell atlas links a cellular stress response state to immunotherapy resistance

Author

Yanshuo Chu, Enyu Dai, Yating Li, Guangchun Han, Guangsheng Pei, Davis R. Ingram, Krupa Thakkar, Jiang-Jiang Qin, Minghao Dang, Xiuning Le, Can Hu, Qing Deng, Ansam Sinjab, Pravesh Gupta, Ruiping Wang, Dapeng Hao, Fuduan Peng, Xinmiao Yan, Yunhe Liu, Shumei Song, Shaojun Zhang, John V. Heymach, Alexandre Reuben, Yasir Y. Elamin, Melissa P. Pizzi, Yang Lu, Rossana Lazcano, Jian Hu, Mingyao Li, Michael Curran, Andrew Futreal, Anirban Maitra, Amir A. Jazaeri, Jaffer A. Ajani, Charles Swanton, Xiang-Dong Cheng, Hussein A. Abbas, Maura Gillison, Krishna Bhat, Alexander J. Lazar, Michael Green, Kevin Litchfield, Humam Kadara, Cassian Yee, and Linghua Wang

Subjects

General Medicine, General Biochemistry, Genetics and Molecular Biology

Published

2023

11. CDH1 loss promotes diffuse-type gastric cancer tumorigenesis via epigenetic reprogramming and immune evasion

Author

Zou Gengyi, Huang Yuanjian, Shengzhe Zhang, Kyung-Pil Ko, Bong Jun Kim, Jie Zhang, Melissa P. Pizzi, Yibo Fan, Sohee Jun, Na Niu, Huamin Wang, Shumei Song, Jaffer A. Ajani, and Jae-Il Park

Abstract

Diffuse-type gastric adenocarcinoma (DGAC) is lethal cancer often diagnosed late and resistant to therapeutics. Although hereditary DGAC is mainly characterized by mutations in theCDH1gene encoding E-cadherin, the impact of E-cadherin inactivation on sporadic DGAC tumorigenesis remains elusive. We found that CDH1 inactivation occurs only subset of DGAC patient tumors. Unsupervised clustering of single-cell transcriptomes of DGAC patient tumors identified two subtypes of DGACs: DGAC1 and DGAC2. The DGAC1 is mainly characterized by CDH1 loss and exhibits distinct molecular signatures and aberrantly activated DGAC-related pathways. Unlike DGAC2 lacking immune cell infiltration in tumors, DGAC1 tumor is enriched with exhausted T cells. To demonstrate the role of CDH1 loss in DGAC tumorigenesis, we established a genetically engineered murine gastric organoid (GOs;Cdh1knock-out [KO],KrasG12D,Trp53KO [EKP]) model recapitulating human DGAC. In conjunction withKrasG12D,Trp53KO (KP),Cdh1KO is sufficient to induce aberrant cell plasticity, hyperplasia, accelerated tumorigenesis, and immune evasion. Additionally, EZH2 was identified as a key regulon promoting CDH1 loss-associated DGAC tumorigenesis. These findings underscore the significance of comprehending the molecular heterogeneity of DGAC and its potential implication for personalized medicine to DGAC patients with CDH1 inactivation.

Published

2023

12. Abstract 1194: Evolution of immune and stromal cell states during the gastric cancer continuum

Author

Ruiping Wang, Shumei Song, Jiangjiang Qin, Katsuhiro Yoshimura, Fuduan Peng, Yanshuo Chu, Yuan Li, Yibo Fan, Jiankang Jin, Minghao Dang, Enyu Dai, Guangsheng Pei, Guangchun Han, Yating Li, Deyali Chatterjee, Melissa P. Pizzi, Ailing W. Scott, Ghia Tatlonghari, Xinmiao Yan, Matheus Da Silva Sewastjanow, Ahmed Adel Fouad Abdelhakeem, Pawel K. Mazur, Xiangdong Cheng, Jaffer A. Ajani, and Linghua Wang

Subjects

Cancer Research, Oncology

Abstract

Introduction: Gastric adenocarcinoma (GAC), a global health burden, lacks detail understanding of the evolution-driven cellular/molecular programs that lead to GAC tumorigenesis followed by progression/metastases. How the TME is orchestrated by precancerous lesions, primary GAC, and in metastatic niches, when well understood, may propel us into an entirely new dimension with the hopes of novel therapeutics. However, only a few studies have investigated the immune/stromal subtypes of GAC with the limitation of scope, cohort size, and/or depth or mainly focused on the primary GACs. Here, we present an atlas of transcriptionally diverse TME across the full continuum of GAC by including peripheral blood, normal gastric tissues, premalignant lesions, localized, and metastatic GACs. Methods: We performed a comprehensive single-cell profiling of 68 specimens collected from 43 subjects including a total of 77,392 high-quality cells which revealed 62 unique cell states uncovering varying profiles. We defined alterations in TMEs that underscore initiation of tumorigenesis to eventual progression. Results: We found a striking preponderance of B lineage cells, primarily the IgA+ plasma cells, in TMEs of the precancerous lesions, whereas 3 immunosuppressive myeloid subsets dominated in advanced GACs. Fractions of GZMK+ effector CD8 T cells and progenitor exhausted CD8 T cells gradually increased as GACs progressed to advanced stages. In addition, our analysis revealed extensive stromal remodeling along the GAC continuum, which may have contributed to enhanced angiogenesis and immune suppressive signaling. The observations in the primary tumors could be validated in an independent scRNA-seq dataset. Notably, we uncovered 3 unique TME interactomes and defined 6 cellular environtypes inhabited by 62 TME cell subsets giving GAC to a novel landscape not yet defined. The two distinct environtypes in GAC primaries are validated in three independent large-scale GAC cohorts, giving credence and definition to previously established histopathological variables, genomic/molecular subtypes and clinical outcomes. The analysis of tumor associated stromal cells discovered SDC2 as an exploitable target to pursue. SDC2 was abundant in cancer associated fibroblasts (CAFs), and the abundance is validated in 3 independent single-cell GAC cohorts as well as at the protein level. SDC2 expression was significantly higher in advanced (vs. early) stages and diffuse (vs. intestinal) type of GAC, and SDC2 overexpression was associated with shorter survival in all 5 large-scale GAC cohorts. Lastly, we assessed the functional effects of SDC2 expression in CAFs on tumor growth in vivo in xenograft models and found SDC2 overexpression in CAFs contributes to tumor growth. Conclusion: This study provides an atlas of GAC TMEs from tumorigenesis to advanced GAC that could be further developed for novel therapeutics but also serves as a community resource. Citation Format: Ruiping Wang, Shumei Song, Jiangjiang Qin, Katsuhiro Yoshimura, Fuduan Peng, Yanshuo Chu, Yuan Li, Yibo Fan, Jiankang Jin, Minghao Dang, Enyu Dai, Guangsheng Pei, Guangchun Han, Yating Li, Deyali Chatterjee, Melissa P. Pizzi, Ailing W. Scott, Ghia Tatlonghari, Xinmiao Yan, Matheus Da Silva Sewastjanow, Ahmed Adel Fouad Abdelhakeem, Pawel K. Mazur, Xiangdong Cheng, Jaffer A. Ajani, Linghua Wang. Evolution of immune and stromal cell states during the gastric cancer continuum [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 1194.

Published

2023