Your search keyword '"Zheng, Yi-Min"' showing total 13 results

1. Neutralization escape, infectivity, and membrane fusion of JN.1-derived SARS-CoV-2 SLip, FLiRT, and KP.2 variants

Author

Li, Pei, Faraone, Julia N., Hsu, Cheng Chih, Chamblee, Michelle, Zheng, Yi-Min, Carlin, Claire, Bednash, Joseph S., Horowitz, Jeffrey C., Mallampalli, Rama K., Saif, Linda J., Oltz, Eugene M., Jones, Daniel, Li, Jianrong, Gumina, Richard J., Xu, Kai, and Liu, Shan-Lu

Abstract

We investigate JN.1-derived subvariants SLip, FLiRT, and KP.2 for neutralization by antibodies in vaccinated individuals, severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2)-infected patients, or class III monoclonal antibody S309. Compared to JN.1, SLip, KP.2, and especially FLiRT exhibit increased resistance to bivalent-vaccinated and BA.2.86/JN.1-wave convalescent human sera. XBB.1.5 monovalent-vaccinated hamster sera robustly neutralize FLiRT and KP.2 but have reduced efficiency for SLip. All subvariants are resistant to S309 and show decreased infectivity, cell-cell fusion, and spike processing relative to JN.1. Modeling reveals that L455S and F456L in SLip reduce spike binding for ACE2, while R346T in FLiRT and KP.2 strengthens it. These three mutations, alongside D339H, alter key epitopes in spike, likely explaining the reduced sensitivity of these subvariants to neutralization. Our findings highlight the increased neutralization resistance of JN.1 subvariants and suggest that future vaccine formulations should consider the JN.1 spike as an immunogen, although the current XBB.1.5 monovalent vaccine could still offer adequate protection.

Published

2024

2. Proteomic and metabolomic features in patients with HCC responding to lenvatinib and anti-PD1 therapy

Author

Li, Zhong-Chen, Wang, Jie, Liu, He-Bin, Zheng, Yi-Min, Huang, Jian-Hang, Cai, Jia-Bin, Zhang, Lei, Liu, Xin, Du, Ling, Yang, Xue-Ting, Chai, Xiao-Qiang, Jiang, Ying-Hua, Ren, Zheng-Gang, Zhou, Jian, Fan, Jia, Yu, De-Cai, Sun, Hui-Chuan, Huang, Cheng, and Liu, Feng

Abstract

Combination therapy (lenvatinib/programmed death-1 inhibitor) is effective for treating unresectable hepatocellular carcinoma (uHCC). We reveal that responders have better overall and progression-free survival, as well as high tumor mutation burden and special somatic variants. We analyze the proteome and metabolome of 82 plasma samples from patients with hepatocellular carcinoma (HCC; n = 51) and normal controls (n = 15), revealing that individual differences outweigh treatment differences. Responders exhibit enhanced activity in the alternative/lectin complement pathway and higher levels of lysophosphatidylcholines (LysoPCs), predicting a favorable prognosis. Non-responders are enriched for immunoglobulins, predicting worse outcomes. Compared to normal controls, HCC plasma proteins show acute inflammatory response and platelet activation, while LysoPCs decrease. Combination therapy increases LysoPCs/phosphocholines in responders. Logistic regression/random forest models using metabolomic features achieve good performance in the prediction of responders. Proteomic analysis of cancer tissues unveils molecular features that are associated with side effects in responders receiving combination therapy. In conclusion, our analysis identifies plasma features associated with uHCC responders to combination therapy.

Published

2024

3. Enhanced neutralization resistance of SARS-CoV-2 Omicron subvariants BQ.1, BQ.1.1, BA.4.6, BF.7, and BA.2.75.2.

Author

Qu, Panke, Evans, John P., Faraone, Julia N., Zheng, Yi-Min, Carlin, Claire, Anghelina, Mirela, Stevens, Patrick, Fernandez, Soledad, Jones, Daniel, Lozanski, Gerard, Panchal, Ashish, Saif, Linda J., Oltz, Eugene M., Xu, Kai, Gumina, Richard J., and Liu, Shan-Lu

Abstract

The continued evolution of SARS-CoV-2 has led to the emergence of several new Omicron subvariants, including BQ.1, BQ.1.1, BA.4.6, BF.7, and BA.2.75.2. Here, we examine the neutralization resistance of these subvariants against sera from 3-dose vaccinated healthcare workers, hospitalized BA.1-wave patients, and BA.4/5-wave patients. We found enhanced neutralization resistance in all new subvariants, especially in the BQ.1 and BQ.1.1 subvariants driven by N460K and K444T mutations, as well as the BA.2.75.2 subvariant driven largely by its F486S mutation. All Omicron subvariants maintained their weakened infectivity in Calu-3 cells, with the F486S mutation driving further diminished titer for the BA.2.75.2 subvariant. Molecular modeling revealed the mechanisms of antibody-mediated immune evasion by R346T, K444T, F486S, and D1199N mutations. Altogether, these findings shed light on the evolution of newly emerging SARS-CoV-2 Omicron subvariants. [Display omitted] • Enhanced neutralization resistance of BQ.1 and BQ.1.1 is driven by N460K and K444T • Enhanced neutralization resistance of BA.2.75.2 is driven by F486S • R346T and K444T contribute to evasion of class III antibody recognition • Modeling reveals that F486S reduces binding for both ACE2 and class I and II antibodies Numerous Omicron subvariants have emerged following BA.4/5 and BA.2.75 subvariants. Qu and colleagues investigate the neutralizing antibody resistance of these subvariants and their ancestral variants. BQ.1, BQ.1.1, BA.4.6, BF.7, and BA.2.75.2 exhibit enhanced neutralizing antibody escape, with BQ.1/BQ.1.1 and BA.2.75.2 driven by N460K/K444T and F486S mutations, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

4. Enhanced evasion of neutralizing antibody response by Omicron XBB.1.5, CH.1.1, and CA.3.1 variants

Author

Qu, Panke, Faraone, Julia N., Evans, John P., Zheng, Yi-Min, Carlin, Claire, Anghelina, Mirela, Stevens, Patrick, Fernandez, Soledad, Jones, Daniel, Panchal, Ashish R., Saif, Linda J., Oltz, Eugene M., Zhang, Baoshan, Zhou, Tongqing, Xu, Kai, Gumina, Richard J., and Liu, Shan-Lu

Abstract

Omicron subvariants continuingly challenge current vaccination strategies. Here, we demonstrate nearly complete escape of the XBB.1.5, CH.1.1, and CA.3.1 variants from neutralizing antibodies stimulated by three doses of mRNA vaccine or by BA.4/5 wave infection, but neutralization is rescued by a BA.5-containing bivalent booster. CH.1.1 and CA.3.1 show strong immune escape from monoclonal antibody S309. Additionally, XBB.1.5, CH.1.1, and CA.3.1 spike proteins exhibit increased fusogenicity and enhanced processing compared with BA.2. Homology modeling reveals the key roles of G252V and F486P in the neutralization resistance of XBB.1.5, with F486P also enhancing receptor binding. Further, K444T/M and L452R in CH.1.1 and CA.3.1 likely drive escape from class II neutralizing antibodies, whereas R346T and G339H mutations could confer the strong neutralization resistance of these two subvariants to S309-like antibodies. Overall, our results support the need for administration of the bivalent mRNA vaccine and continued surveillance of Omicron subvariants.

Published

2023

5. Evasion of neutralizing antibody responses by the SARS-CoV-2 BA.2.75 variant.

Author

Qu, Panke, Evans, John P., Zheng, Yi-Min, Carlin, Claire, Saif, Linda J., Oltz, Eugene M., Xu, Kai, Gumina, Richard J., and Liu, Shan-Lu

Abstract

The newly emerged BA.2.75 severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) variant contains 9 additional mutations in its spike (S) protein compared to the ancestral BA.2 variant. Here, we examine the neutralizing antibody escape of BA.2.75 in mRNA-vaccinated and BA.1-infected individuals, as well as the molecular basis underlying functional changes in S. Notably, BA.2.75 exhibits enhanced neutralization resistance over BA.2 but less than the BA.4/5 variant. The G446S and N460K mutations of BA.2.75 are primarily responsible for its enhanced resistance to neutralizing antibodies. The R493Q mutation, a reversion to the prototype sequence, reduces BA.2.75 neutralization resistance. The impact of these mutations is consistent with their locations in common neutralizing antibody epitopes. Further, BA.2.75 shows enhanced cell-cell fusion over BA.2, driven largely by the N460K mutation, which enhances S processing. Structural modeling reveals enhanced receptor contacts introduced by N460K, suggesting a mechanism of potentiated receptor utilization and syncytia formation. • BA.2.75 shows enhanced neutralization resistance and fusion over BA.2 but not BA.4/5 • G446S, and to a lesser extent N460K, determines enhanced neutralization resistance • N460K drives enhanced spike processing and cell-cell fusion of BA.2.75 • N460K potentiates ACE2 interactions likely by forming a salt bridge and hydrogen bond Newly emerged Omicron subvariants reignite concerns over escape from existing immunity. Qu and colleagues compare the immunity resistance and fusogenicity of BA.2.75 with prior variants. BA.2.75 exhibits stronger neutralization resistance than BA.2 but weaker than BA.4/5, as well as enhanced fusogenicity, which are largely driven by G446S and N460K, respectively. [ABSTRACT FROM AUTHOR]

Published

2022

6. Neutralization escape of Omicron XBB, BR.2, and BA.2.3.20 subvariants

Author

Faraone, Julia N., Qu, Panke, Evans, John P., Zheng, Yi-Min, Carlin, Claire, Anghelina, Mirela, Stevens, Patrick, Fernandez, Soledad, Jones, Daniel, Lozanski, Gerard, Panchal, Ashish, Saif, Linda J., Oltz, Eugene M., Gumina, Richard J., and Liu, Shan-Lu

Abstract

New Omicron subvariants continue to emerge throughout the world. In particular, the XBB subvariant, which is a recombinant virus between BA.2.10.1.1 and BA.2.75.3.1.1.1, as well as the BA.2.3.20 and BR.2 subvariants that contain mutations distinct from BA.2 and BA.2.75, are currently increasing in proportion of variants sequenced. Here we show that antibodies induced by 3-dose mRNA booster vaccination as well as BA.1- and BA.4/5-wave infection effectively neutralize BA.2, BR.2, and BA.2.3.20 but have significantly reduced efficiency against XBB. In addition, the BA.2.3.20 subvariant exhibits enhanced infectivity in the lung-derived CaLu-3 cells and in 293T-ACE2 cells. Overall, our results demonstrate that the XBB subvariant is highly neutralization resistant, which highlights the need for continued monitoring of the immune escape and tissue tropism of emerging Omicron subvariants.

Published

2023

7. Continued evasion of neutralizing antibody response by Omicron XBB.1.16

Author

Faraone, Julia N., Qu, Panke, Zheng, Yi-Min, Carlin, Claire, Jones, Daniel, Panchal, Ashish R., Saif, Linda J., Oltz, Eugene M., Gumina, Richard J., and Liu, Shan-Lu

Abstract

The evolution of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) continues to challenge the efficacy of vaccination efforts against coronavirus disease 2019 (COVID-19). The Omicron XBB lineage of SARS-CoV-2 has presented dramatic evasion of neutralizing antibodies stimulated by mRNA vaccination and COVID-19 convalescence. XBB.1.16, characterized by two mutations relative to the dominating variant XBB.1.5, i.e., E180V and K478R, has been on the rise globally. In this study, we compare the immune escape of XBB.1.16 with XBB.1.5, alongside ancestral variants D614G, BA.2, and BA.4/5. We demonstrate that XBB.1.16 is strongly immune evasive, with extent comparable to XBB.1.5 in bivalent-vaccinated healthcare worker sera, 3-dose-vaccinated healthcare worker sera, and BA.4/5-wave convalescent sera. Interestingly, the XBB.1.16 spike is less fusogenic than that of XBB.1.5, and this phenotype requires both E180V and K478R mutations to manifest. Overall, our findings emphasize the importance of the continued surveillance of variants and the need for updated mRNA vaccine formulations.

Published

2023

8. Neutralization of SARS-CoV-2 Omicron sub-lineages BA.1, BA.1.1, and BA.2.

Author

Evans, John P., Zeng, Cong, Qu, Panke, Faraone, Julia, Zheng, Yi-Min, Carlin, Claire, Bednash, Joseph S., Zhou, Tongqing, Lozanski, Gerard, Mallampalli, Rama, Saif, Linda J., Oltz, Eugene M., Mohler, Peter J., Xu, Kai, Gumina, Richard J., and Liu, Shan-Lu

Abstract

Recent reports of SARS-CoV-2 Omicron variant sub-lineages, BA.1, BA.1.1, and BA.2, have reignited concern over potential escape from vaccine- and infection-induced immunity. We examine the sensitivity of these sub-lineages and other major variants to neutralizing antibodies from mRNA-vaccinated and boosted individuals, as well as recovered COVID-19 patients, including those infected with Omicron. We find that all Omicron sub-lineages, especially BA.1 and BA.1.1, exhibit substantial immune escape that is largely overcome by mRNA vaccine booster doses. While Omicron BA.1.1 escapes almost completely from neutralization by early-pandemic COVID-19 patient sera and to a lesser extent from sera of Delta-infected patients, BA.1.1 is sensitive to Omicron-infected patient sera. Critically, all Omicron sub-lineages, including BA.2, are comparably neutralized by Omicron patient sera. These results highlight the importance of booster vaccine doses for protection against all Omicron variants and provide insight into the immunity from natural infection against Omicron sub-lineages. [Display omitted] • BA.1.1, BA.1, and BA.2 escape neutralization by two-dose mRNA vaccinee sera • Booster vaccination recovers Omicron immunity to levels comparable to Delta • Sera from Omicron, but not D614G or Delta, COVID-19 patients neutralize Omicron • The Omicron "EPE214" insertion does not dictate neutralization resistance The emerging SARS-CoV-2 Omicron variants may threaten existing COVID-19 immunity. Evans and colleagues examine immunity against the BA.1.1 and BA.2 variants, as well as prior SARS-CoV-2 variants, in two- and three-dose vaccinated individuals and recovered COVID-19 patients. Booster vaccination, but not two-dose vaccinee or non-Omicron-infected patient sera, neutralizes Omicron. [ABSTRACT FROM AUTHOR]

Published

2022

9. IFITM Proteins Restrict HIV-1 Infection by Antagonizing the Envelope Glycoprotein

Author

Yu, Jingyou, Li, Minghua, Wilkins, Jordan, Ding, Shilei, Swartz, Talia H., Esposito, Anthony M., Zheng, Yi-Min, Freed, Eric O., Liang, Chen, Chen, Benjamin K., and Liu, Shan-Lu

Abstract

The interferon-induced transmembrane (IFITM) proteins have been recently shown to restrict HIV-1 and other viruses. Here, we provide evidence that IFITM proteins, particularly IFITM2 and IFITM3, specifically antagonize the HIV-1 envelope glycoprotein (Env), thereby inhibiting viral infection. IFITM proteins interact with HIV-1 Env in viral producer cells, leading to impaired Env processing and virion incorporation. Notably, the level of IFITM incorporation into HIV-1 virions does not strictly correlate with the extent of inhibition. Prolonged passage of HIV-1 in IFITM-expressing T lymphocytes leads to emergence of Env mutants that overcome IFITM restriction. The ability of IFITMs to inhibit cell-to-cell infection can be extended to HIV-1 primary isolates, HIV-2 and SIVs; however, the extent of inhibition appears to be virus-strain dependent. Overall, our study uncovers a mechanism by which IFITM proteins specifically antagonize HIV-1 Env to restrict HIV-1 infection and provides insight into the specialized role of IFITMs in HIV infection.

Published

2015

10. Finite element model updating of a long-span steel skybridge.

Author

ZHENG Yi-min, SUN Hua-hua, ZHAO Xin, CHEN Wei, ZHANG Rong-hai2, and SHEN Xu-dong2

Subjects

SKYWALKS, IRON & steel bridges, LONG-span bridges, MODAL assurance criterion, PARAMETER estimation, DYNAMIC testing

Abstract

Hanzhou Citizen Center is a complex connected tall building, in which six hexadic-towers are connected to each other through six skybridges. The finite element model updating of the steel skybridge was conducted using the sensitivity-based and Bayesian estimation updating methods. The relative error of the frequencies and Modal Assurance Criterion (MAC) values of the modal shapes were firstly computed, then the dynamic characteristic differences between numerical model and real structure were obtained by comparing the calculated modal parameters and the estimated modal parameters through dynamic testing under the ambient excitation. The sensitivity matrix was constructed through differential computation for modal parameters with respect to all selected structural parameters and then the insensitive parameters were sieved. The parameter weighting matrix and response weighting matrix were obtained using the Bayesian estimation method. Based on the confidence values of initial designed parameters, the allowable lower and upper bounds were applied for the parameters values. The iterative updating procedure was conducted according to the convergence criterion. From the updating results, it is, found that there was a good correlation between the dynamic characteristics of updated model and estimated dynamic characteristics through dynamic testing. The updated model can then be used for vibration control, response prediction and condition assessment of the skybridge in future. [ABSTRACT FROM AUTHOR]

Published

2009

11. Identification of a meander region proline residue critical for heme binding to cytochrome P450...

Author

Zheng, Yi-Min and Fisher, Michael B.

Published

1998

12. SERINC proteins potentiate antiviral type I IFN production and proinflammatory signaling pathways

Author

Zeng, Cong, Waheed, Abdul A., Li, Tianliang, Yu, Jingyou, Zheng, Yi-Min, Yount, Jacob S., Wen, Haitao, Freed, Eric O., and Liu, Shan-Lu

Abstract

Description

Published

2021

13. Positional Specificity of Rabbit CYP4B1 for ω-Hydroxylation1of Short-Medium Chain Fatty Acids and Hydrocarbons

Author

Fisher, Michael B., Zheng, Yi-Min, and Rettie, Allan E.

Abstract

Rabbit CYP4B1 was incubated with a series of fatty acid and hydrocarbon substrates and metabolites were identified by gas chromatography and gas chromatography/mass spectrometry. C-7 to C-10 n-alkyl fatty acids were preferentially hydroxylated at the terminal carbon (ω/ω-1 = 1.1–7.4) with turnover numbers of 1–11 min−1. The C-7 to C-10 n-alkyl hydrocarbons exhibited turnover numbers of 11–33 min−1for the corresponding reactions and even higher regioselectivities for hydroxylation at the thermodynamically disfavored site (ω/ω-1 = 1.6–23). These results demonstrate a functional link between CYP4B1 and other CYP4 fatty acid hydroxylases, and show further that CYP4B1's unusual positional specificity is not dictated by the presence of a carboxylate (or polar) anchor on the substrate. This suggests the presence of a dominant hydrocarbon binding site which effectively restricts the access of short-medium chain n-alkyl substrates to the perferryl species in the active site of rabbit CYP4B1.

Published

1998