Project description:Hepatocellular carcinoma (HCC) is still one of the malignant tumors with high morbidity and mortality in China and worldwide. Although AFP have been widely used as important biomarkers for HCC diagnosis and evaluation, the AFP level has a huge variation among HCC patient populations. Understanding the intrinsic heterogeneities of HCC associated with AFP levels is essential for the molecular mechanism studies of HCC with different AFP levels as well as for the potential early diagnosis and personalized treatment of HCC with AFP negative. Here, an integrated glycoproteomic and proteomic analysis of low and high AFP level of HCC tumors was performed to investigate the intrinsic heterogeneities of site-specific glycosylation associated with different AFP levels of HCC. we identified many commonly altered site-specific glycans from HCC tumors regardless of AFP levels, including decreased modifications by oligo-mannose and sialylated bi-antennary glycans, and increased modifications by bisecting glycans. By relative quantifying the intact glycopeptides between low and high AFP tumor groups, the great heterogeneities of site-specific N-glycans between two groups of HCC tumors were also uncovered. We found that several sialylated but not core fucosylated tri-antennary glycans were uniquely high-regulated in low AFP level of HCC tumors, while many core fucosylated bi-antennary or hybrid glycans as well as bisecting glycans were uniquely increased in high AFP tumors. The data provide a valuable resource for future HCC studies regarding the mechanism, heterogeneities and new biomarker discovery.

Project description:In this study,we performed integrated glycoproteomic and global proteomic analysis of tumor tissues of ICC and HCC to investigate the differences in site-specific glycosylation and proteins between ICC and HCC tumors. The paired paracancer tissue were also included as controls to determine the site-specific glycosylation changes in ICC and HCC tumors. The alteration extents in glycopeptide, global proteome, and normalized glycosylation in different sample groups were systematically compared.

Project description:The routine study of human malaria liver-stage biology in vitro is hampered by low infection efficiency of human hepatocellular carcinoma (HCC) lines (<0.1%), poor understanding of steady-state HCC biology, and lack of appropriate tools for trace sample analysis. HC-04 is the only HCC that supports complete development of human malaria parasites. We hypothesized that HCCs are in various intermediate stages of the epithelial-mesenchymal transition (EMT) and HC-04s retain epithelial characteristics that permit infection. We developed an novel analytical approach to test this hypothesis viz. the HC-04 response to hepatocyte growth factor (HGF). We used online two-dimensional liquid chromatography tandem mass spectrometry (2D-LC-MS/MS) to quantify protein expression profiles in HC-04 pre-/post-HGF treatment and validated these results by RT-qPCR and microscopy. We successfully increased protein identification efficiency over offline-2D methods by 12-fold using less sample material, allowing robust protein quantification. We observed expected up-regulation and down-regulation of EMT protein markers in response to HGF, but also unexpected cellular responses. HC-04 is thus susceptible to HGF-mediated signaling but to a lesser degree than what we observed for HepG2, a widely used, but poor malaria HCC model. Our analytical approach to understanding the basic biology of HC-04 helps us understand the factors that may influence its utility as a model for malaria liver-stage development. We observed that HC-04 treatment with HGF prior to the addition of Plasmodium falciparum sporozoites did not facilitate cell invasion, arguing for unlinking the effect of HGF on malaria liver stage development from hepatocyte invasion. Finally, our 2D-LC-MS/MS approach and broadly applicable experimental strategy should prove useful in the analysis of various hepatocyte-pathogen interactions, tumor progression and early disease events.

Project description:The routine study of human malaria liver-stage biology in vitro is hampered by low infection efficiency of human hepatocellular carcinoma (HCC) lines (<0.1%), poor understanding of steady-state HCC biology, and lack of appropriate tools for trace sample analysis. HC-04 is the only HCC that supports complete development of human malaria parasites. We hypothesized that HCCs are in various intermediate stages of the epithelial-mesenchymal transition (EMT) and HC-04s retain epithelial characteristics that permit infection. We developed an novel analytical approach to test this hypothesis viz. the HC-04 response to hepatocyte growth factor (HGF). We used online two-dimensional liquid chromatography tandem mass spectrometry (2D-LC-MS/MS) to quantify protein expression profiles in HC-04 pre-/post-HGF treatment and validated these results by RT-qPCR and microscopy. We successfully increased protein identification efficiency over offline-2D methods by 12-fold using less sample material, allowing robust protein quantification. We observed expected up-regulation and down-regulation of EMT protein markers in response to HGF, but also unexpected cellular responses. HC-04 is thus susceptible to HGF-mediated signaling but to a lesser degree than what we observed for HepG2, a widely used, but poor malaria HCC model. Our analytical approach to understanding the basic biology of HC-04 helps us understand the factors that may influence its utility as a model for malaria liver-stage development. We observed that HC-04 treatment with HGF prior to the addition of Plasmodium falciparum sporozoites did not facilitate cell invasion, arguing for unlinking the effect of HGF on malaria liver stage development from hepatocyte invasion. Finally, our 2D-LC-MS/MS approach and broadly applicable experimental strategy should prove useful in the analysis of various hepatocyte-pathogen interactions, tumor progression and early disease events.

Project description:While altered protein glycosylation is regarded a trait of oral squamous cell carcinoma (OSCC), its heterogeneous glycoproteome and dynamics with disease progression remain unmapped. Employing an integrated multi-omics approach comprising unbiased and quantitative glycomics and glycoproteomics on resected OSCC tissues, we firstly profiled the N-glycome that overall displayed uniform expression in OSCC patients with (N+, n = 19) and without (N0, n = 12) lymph node metastasis, suggesting relatively stable N-glycosylation during metastasis. Notably, glycoproteomics and advanced correlation analysis uncovered altered site-specific N-glycosylation and associations with clinicopathological features. Importantly, targeted analyses of the multi-omics data unveiled two N-glycans and three N-glycopeptides that were closely associated with patient survival. This study provides novel insight into the complex OSCC tissue N-glycoproteome forming an important resource to further explore the underpinning disease mechanisms and uncover new prognostic glyco-markers for OSCC.

Project description:N-linked glycoproteins are known to be important for spermatozoa development and gametes fusion. However, little is known about detailed information of these glycoproteins, particularly the glycosylation sites and its corresponding glycan structures in human spermatozoa. In present study, an in house software coupled with LC-MS/MS analysis of intact glycopeptides was employed to establish a large scale of site-specific N-glycoproteome map in human spermatozoa. The results mapped the large-scale N-glycoproteins in human spermatozoa and interpreted the precise glycan structures with the corresponding glycosites. These presented data laid the foundation for the exploration of biological function of glycosylation on human spermatozoa and glycan structure involved male infertility.

Project description:The heart of a newborn mouse has an exceptional capacity to regenerate from myocardial injury but lose it after a week of life, which has been utilized as a valuable model to explore the cues for heart regeneration. More and more researches indicated that glycoprotein played an important role in cardiac regeneration. Elucidating the glycosylation processes associated with heart regeneration will be beneficial for the molecular mechanism studies of heart regeneration as well as discovery of potential therapeutic strategies for human cardiac diseases. In this work, an integrated glycoproteomic and proteomic analysis were performed to investigate the differences in glycoprotein abundances and site-specific glycosylation occupancy between neonatal day 1 (P1) and day 7 (P7) of mouse hearts. The intact glycoepeptides were enriched and identified in both P1 and P7 hearts. To screen for differentially regulated glycoproteins, we compared the expression levels of intact glycopeptides between P1 and P7 hearts using label free quantification. Eventually, the glycosylation occupancy of site-specific N-glycans were obtained by comparing the alterations of intact glycopeptides with their corresponding protein expression levels obtained from global proteomic analysis. These altered glycosylation patterns among proteins between P1 and P7 mouse hearts have a significant potential to aid our understanding of the regenerative capacity loss in neonatal mouse hearts during the first week, thus leading to novel therapeutic approaches to recover the capacity.

Project description:HGF sensitizes ovarian cancer cells to chemotherapeutics, e.g. cisplatin (CDDP), through a signaling cascade activated by its MET oncogene encoded receptor and transduced by the p38MAPK. This cascade results in the regulation of a common set of transcripts in three ovarian cancer cell lines, with different genetic profiles and susceptibility to drugs. In order to elucidate the mechanism of HGF dependent cell sensitization to drugs, the transcriptional response of the three ovarian cancer cell lines to HGF and CDDP were studied by microarray based transcription profiling

Project description:Cementum protein 1 (CEMP1) is involved in cell adhesion, cell differentiation, regulates the mineralization processes during cementogenesis, and selects progenitor cells from periodontal ligament. To determine the gene expression profiling induced by CEMP1 overexpression by non-osteogenic cells such as human gingival fibroblasts we performed microarrays (Human Gene 1.0 ST, Affymetrix) to identify differentially expressed transcripts (ED) between human gingival fibroblasts (HGF) and those that overexpress CEMP1 (HGF/CEMP1). HGF cells overexpressing CEMP1 and controls were harvested at 3, 7 and 14 days after transfection of CEMP1, three biological replicates were analyzed for each time point and condition for a total of 18 microarrays.

Project description:We aimed to in-depth characterize and quantify salivary N-glycoproteomics. HILIC enrichment and LC-MS/MS were combined to investigate salivary glycosylation both at deglycopeptides level and glycopepeptides level, and alterations in site-specific glycoforms for human saliva were detected between lung cancer patients and healthy subjects. Firstly, intact glycopeptides were enriched from human saliva through using HILIC. Obtained intact glycopeptides were characterized by LC-MS/MS directly. Furthermore, the glycosylation sites were fully identified by LC-MS/MS followed by incubating with PNGase F. The developed workflow was applied to compare N-glycosites and intact N-glycopeptides in lung cancer group and healthy control group. Dysregulated N-glycosites as well as site-specific glycoforms were confidently observed in lung cancer and their potential value in clinical applications will be discussed.