Your search keyword '"Wang, Ziqiu"' showing total 26 results

1. High Performance Nacre Fibers by Engineering Interfacial Entanglement.

Author

Wang, Lidan, Li, Kaiwen, Chen, Feifan, Guo, Rui, Zhao, Yanyan, Liu, Senping, Zhang, Yiwei, Li, Zeshen, Shen, Chenwei, Wang, Ziqiu, Ming, Xin, Liu, Yingjun, Chen, Yan, Liu, Yilun, Gao, Chao, and Xu, Zhen

Published

2024

2. High Performance Nacre Fibers by Engineering Interfacial Entanglement

Author

Wang, Lidan, Li, Kaiwen, Chen, Feifan, Guo, Rui, Zhao, Yanyan, Liu, Senping, Zhang, Yiwei, Li, Zeshen, Shen, Chenwei, Wang, Ziqiu, Ming, Xin, Liu, Yingjun, Chen, Yan, Liu, Yilun, Gao, Chao, and Xu, Zhen

Abstract

Biological materials exhibit fascinating mechanical properties for intricate interactions at multiple interfaces to combine superb toughness with wondrous strength and stiffness. Recently, strong interlayer entanglement has emerged to replicate the powerful dissipation of natural proteins and alleviate the conflict between strength and toughness. However, designing intricate interactions in a strong entanglement network needs to be further explored. Here, we modulate interlayer entanglement by introducing multiple interactions, including hydrogen and ionic bonding, and achieve ultrahigh mechanical performance of graphene-based nacre fibers. Two essential modulating trends are directed. One is modulating dynamic hydrogen bonding to improve the strength and toughness up to 1.58 GPa and 52 MJ/m3, simultaneously. The other is tailoring ionic coordinating bonding to raise the strength and stiffness, reaching 2.3 and 253 GPa. Modulating various interactions within robust entanglement provides an effective approach to extend performance limits of bioinspired nacre and optimize multiscale interfaces in diverse composites.

Published

2024

3. Superior Strong and Tough Nacre-Inspired Materials by Interlayer Entanglement.

Author

Wang, Lidan, Wang, Bo, Wang, Ziqiu, Huang, Jiajing, Li, Kaiwen, Liu, Senping, Lu, Jiahao, Han, Zhanpo, Gao, Yue, Cai, Gangfeng, Liu, Yingjun, Chen, Yan, Lin, Yue, Liu, Yilun, Gao, Chao, and Xu, Zhen

Published

2023

4. Plastic-Swelling Preparation of Functional Graphene Aerogel Fiber Textiles

Author

Qi, Yuxiang, Xia, Yuxing, Li, Peng, Wang, Ziqiu, Ming, Xin, Wang, Bo, Shen, Kai, Cai, Gangfeng, Li, Kaiwen, Gao, Yue, Liu, Yingjun, Gao, Chao, and Xu, Zhen

Abstract

Graphical Abstract:

Published

2023

5. One-Pot, One-Step Synthesis of Drug-Loaded Magnetic Multimicelle Aggregates.

Author

Kim, Chang Soo, Nevozhay, Dmitry, Aburto, Rebeca Romero, Pehere, Ashok, Pang, Lan, Dillard, Rebecca, Wang, Ziqiu, Smith, Clayton, Mathieu, Kelsey Boitnott, Zhang, Marie, Hazle, John D., Bast Jr., Robert C., and Sokolov, Konstantin

Published

2022

6. Highly Thermally Conductive and Structurally Ultra-Stable Graphitic Films with Seamless Heterointerfaces for Extreme Thermal Management

Author

Zhang, Peijuan, Hao, Yuanyuan, Shi, Hang, Lu, Jiahao, Liu, Yingjun, Ming, Xin, Wang, Ya, Fang, Wenzhang, Xia, Yuxing, Chen, Yance, Li, Peng, Wang, Ziqiu, Su, Qingyun, Lv, Weidong, Zhou, Ji, Zhang, Ying, Lai, Haiwen, Gao, Weiwei, Xu, Zhen, and Gao, Chao

Abstract

Presenting the first investigation into the structurally bubbling-failure mechanism of graphitic film during cyclic liquid nitrogen shocks.Proposing an innovative design about seamless heterointerface constructing a Cu-modified structure.Inventing a new ultra-stable species of highly thermally conductive films to inspire new techniques for efficient and extreme thermal management.

Published

2024

7. One-Pot, One-Step Synthesis of Drug-Loaded Magnetic Multimicelle Aggregates

Author

Kim, Chang Soo, Nevozhay, Dmitry, Aburto, Rebeca Romero, Pehere, Ashok, Pang, Lan, Dillard, Rebecca, Wang, Ziqiu, Smith, Clayton, Mathieu, Kelsey Boitnott, Zhang, Marie, Hazle, John D., Bast, Robert C., and Sokolov, Konstantin

Abstract

Lipid-based formulations provide a nanotechnology platform that is widely used in a variety of biomedical applications because it has several advantageous properties including biocompatibility, reduced toxicity, relative ease of surface modifications, and the possibility for efficient loading of drugs, biologics, and nanoparticles. A combination of lipid-based formulations with magnetic nanoparticles such as iron oxide was shown to be highly advantageous in a growing number of applications including magnet-mediated drug delivery and image-guided therapy. Currently, lipid-based formulations are prepared by multistep protocols. Simplification of the current multistep procedures can lead to a number of important technological advantages including significantly decreased processing time, higher reaction yield, better product reproducibility, and improved quality. Here, we introduce a one-pot, single-step synthesis of drug-loaded magnetic multimicelle aggregates (MaMAs), which is based on controlled flow infusion of an iron oxide nanoparticle/lipid mixture into an aqueous drug solution under ultrasonication. Furthermore, we prepared molecular-targeted MaMAs by directional antibody conjugation through an Fc moiety using Cu-free click chemistry. Fluorescence imaging and quantification confirmed that antibody-conjugated MaMAs showed high cell-specific targeting that was enhanced by magnetic delivery.

Published

2022

8. Study on dynamic characteristics of leaf spring system in vibration screen

Author

Zhou, Jiacheng, Hu, Chao, Wang, Ziqiu, Ren, Zhengfa, Wang, Xiaoyu, and Mao, Kuanmin

Abstract

By studying dynamic characteristics of the leaf spring system, a new elastic component is designed to reduce the working load and to a certain extent to ensure the linearity as well as increase the amplitude in the vertical and horizontal directions in vibration screen. The modal parameters, amplitudes, and amplification factors of the leaf spring system are studied by simulation and experiment. The modal results show that the leaf spring system vibrates in horizontal and vertical directions in first and second mode shapes, respectively. It is conducive to loosening and moving the particles on the vibration screen. In addition, it is found that the maximum amplitude and amplification factor in the horizontal direction appear at 300 r/min (5 Hz) while those in the vertical direction appear at 480 r/min (8 Hz), which are higher than those in the disc spring system. Moreover, the amplitude of the leaf spring system increases proportionally with the increase of exciting force while the amplification factors are basically the same under different exciting forces, indicating the good linearity of the leaf spring system. Furthermore, the minimum exciting force occurs in the leaf spring system under the same amplitude by comparing the exciting force among different elastic components. The above works can provide guidance for the industrial production in vibration screen.

Published

2021

9. The Origin of the Sheet Size Predicament in Graphene Macroscopic Papers.

Author

Lin, Jiahao, Li, Peng, Liu, Yingjun, Wang, Ziqiu, Wang, Ya, Ming, Xin, Gao, Chao, and Xu, Zhen

Published

2021

10. Surface-fill hydrogel attenuates the oncogenic signature of complex anatomical surface cancer in a single application

Author

Majumder, Poulami, Singh, Anand, Wang, Ziqiu, Dutta, Kingshuk, Pahwa, Roma, Liang, Chen, Andrews, Caroline, Patel, Nimit L., Shi, Junfeng, de Val, Natalia, Walsh, Scott T. R., Jeon, Albert Byungyun, Karim, Baktiar, Hoang, Chuong D., and Schneider, Joel P.

Abstract

Tumours growing in a sheet-like manner on the surface of organs and tissues with complex topologies represent a difficult-to-treat clinical scenario. Their complete surgical resection is difficult due to the complicated anatomy of the diseased tissue. Residual cancer often responds poorly to systemic therapy and locoregional treatment is hindered by the limited accessibility to microscopic tumour foci. Here we engineered a peptide-based surface-fill hydrogel (SFH) that can be syringe- or spray-delivered to surface cancers during surgery or used as a primary therapy. Once applied, SFH can shape change in response to alterations in tissue morphology that may occur during surgery. Implanted SFH releases nanoparticles composed of microRNA and intrinsically disordered peptides that enter cancer cells attenuating their oncogenic signature. With a single application, SFH shows efficacy in four preclinical models of mesothelioma, demonstrating the therapeutic impact of the local application of tumour-specific microRNA, which might change the treatment paradigm for mesothelioma and possibly other surface cancers.

Published

2021

11. Particle Size Distributions for Cellulose Nanocrystals Measured by Transmission Electron Microscopy: An Interlaboratory Comparison.

Author

Meija, Juris, Bushell, Michael, Couillard, Martin, Beck, Stephanie, Bonevich, John, Cui, Kai, Foster, Johan, Will, John, Fox, Douglas, Cho, Whirang, Heidelmann, Markus, Park, Byong Chon, Park, Yun Chang, Ren, Lingling, Xu, Li, Stefaniak, Aleksandr B., Knepp, Alycia K., Theissmann, Ralf, Purwin, Horst, and Wang, Ziqiu

Published

2020

12. Toward the Understanding of Small Protein-Mediated Collagen Intrafibrillar Mineralization.

Author

Wang, Ziqiu, Ustriyana, Putu, Chen, Kexun, Zhao, Weilong, Xu, Zhijun, and Sahai, Nita

Published

2020

13. The Origin of the Sheet Size Predicament in Graphene Macroscopic Papers

Author

Lin, Jiahao, Li, Peng, Liu, Yingjun, Wang, Ziqiu, Wang, Ya, Ming, Xin, Gao, Chao, and Xu, Zhen

Abstract

The larger size of graphene sheets should intuitively generate higher overall properties of their macroscopic materials. However, this intuitive notion still remains ambiguous. Here, we uncover that the wrinkle formation causes the counterintuitive size predicament of graphene sheets in their macroscopic materials. In the model of graphene oxide assembled papers, we reveal that the giant size of graphene oxide sheets aggravates the formation of larger wrinkles and more microvoids, causing the negative size effect in mechanical strength. A major microscopic origin of the size predicament is the skin wrinkling in the drying process, and the wrinkling behavior follows a general rule of deformation of an elastic thin plate. We use a wrinkle-engineering strategy to depress the spontaneously formed large wrinkles and succeed in the resolution of the size predicament. After wrinkle modulation, an authentically positive size effect reversely appears in which giant graphene sheets generate ultrahigh mechanical strength and superior functionalities of graphene papers. The origin of the size predicament reminds us of the hidden importance of modulating wrinkles for graphene macroscopic materials and provides a guidance of wrinkle engineering for graphene materials with advanced performances.

Published

2021

14. Particle Size Distributions for Cellulose Nanocrystals Measured by Transmission Electron Microscopy: An Interlaboratory Comparison

Author

Meija, Juris, Bushell, Michael, Couillard, Martin, Beck, Stephanie, Bonevich, John, Cui, Kai, Foster, Johan, Will, John, Fox, Douglas, Cho, Whirang, Heidelmann, Markus, Park, Byong Chon, Park, Yun Chang, Ren, Lingling, Xu, Li, Stefaniak, Aleksandr B., Knepp, Alycia K., Theissmann, Ralf, Purwin, Horst, Wang, Ziqiu, de Val, Natalia, and Johnston, Linda J.

Abstract

Particle size is a key parameter that must be measured to ensure reproducible production of cellulose nanocrystals (CNCs) and to achieve reliable performance metrics for specific CNC applications. Nevertheless, size measurements for CNCs are challenging due to their broad size distribution, irregular rod-shaped particles, and propensity to aggregate and agglomerate. We report an interlaboratory comparison (ILC) that tests transmission electron microscopy (TEM) protocols for image acquisition and analysis. Samples of CNCs were prepared on TEM grids in a single laboratory, and detailed data acquisition and analysis protocols were provided to participants. CNCs were imaged and the size of individual particles was analyzed in 10 participating laboratories that represent a cross section of academic, industrial, and government laboratories with varying levels of experience with imaging CNCs. The data for each laboratory were fit to a skew normal distribution that accommodates the variability in central location and distribution width and asymmetries for the various datasets. Consensus values were obtained by modeling the variation between laboratories using a skew normal distribution. This approach gave consensus distributions with values for mean, standard deviation, and shape factor of 95.8, 38.2, and 6.3 nm for length and 7.7, 2.2, and 2.9 nm for width, respectively. Comparison of the degree of overlap between distributions for individual laboratories indicates that differences in imaging resolution contribute to the variation in measured widths. We conclude that the selection of individual CNCs for analysis and the variability in CNC agglomeration and staining are the main factors that lead to variations in measured length and width between laboratories.

Published

2020

15. Toward the Understanding of Small Protein-Mediated Collagen Intrafibrillar Mineralization

Author

Wang, Ziqiu, Ustriyana, Putu, Chen, Kexun, Zhao, Weilong, Xu, Zhijun, and Sahai, Nita

Abstract

The design of improved materials for orthopedic implants and bone tissue engineering scaffolds relies on materials mimicking the properties of bone. Calcium phosphate (Ca-PO4)-mineralized collagen fibrils arranged in a characteristic hierarchical structure constitute the building blocks of mineralized vertebrate tissues and control their biomechanical and biochemical properties. Large, flexible, acidic noncollagenous proteins (ANCPs) have been shown to influence collagen mineralization but little is known about mineralization mechanisms with the aid of small proteins. Osteocalcin (OCN) is a small, highly structured biomolecule known as a multifunctional hormone in its undercarboxylated form. Here, we examined the potential mechanism of collagen intrafibrillar mineralization in vitromediated by OCN as a model protein. Rapid and random extrafibrillar mineralization of flakey Ca-PO4particles was observed by transmission electron microscopy mainly on the outer surfaces of collagen fibrils of a preformed collagen scaffold in the absence of the protein. In contrast, the protein stabilized hydrated, spherical nanoclusters of Ca-PO4on the outer surface of the fibrils, thereby retarding extrafibrillar mineralization. The nanoclusters then infiltrated the fibrils resulting in intrafibrillar mineralization with HAP crystals aligned with the fibrils. This mechanism is similar to that observed for unstructured ANCPs. Results of fibrillogenesis and immunogold labeling studies showed that OCN was associated primarily with the fibrils, consistent with ex vivostudies on mineralizing turkey tendon. The present findings contribute to expanding our understanding of collagen intrafibrillar mineralization and provide insight into design synthetic macromolecular matrices for orthopedic implants and bone regeneration.

Published

2020

16. Structure–Activity Relationships of Hydroxyapatite-Binding Peptides

Author

Ling, Chen, Zhao, Weilong, Wang, Ziqiu, Chen, Jiadong, Ustriyana, Putu, Gao, Min, and Sahai, Nita

Abstract

Elucidating the structure–activity relationships between biomolecules and hydroxyapatite (HAP) is essential to understand bone mineralization mechanisms, develop HAP-based implants, and design drug delivery vectors. Here, four peptides identified by phage display were selected as model HAP-binding peptides (HBPs) to examine the effects of primary amino acid sequence, phosphorylation of serine, presence of charged amino acid residues, and net charge of the peptide on (1) HAP-binding affinity, (2) secondary conformation, and (3) HAP nucleation and crystal growth. Binding affinities were determined by obtaining adsorption isotherms by mass depletion, and the conformations of the peptides in solution and bound states were observed by circular dichroism. Results showed that the magnitude of the net charge primarily controlled binding affinity, with little dependence on the other HBP features. The binding affinity and conformation results were in good agreement with our previous molecular dynamics simulation results, thus providing an excellent benchmark for the simulations. Transmission electron microscopy was used to explore the effect of these HBPs on calcium phosphate (Ca-PO4) nucleation and growth. Results indicated that HBPs may inhibit nucleation of Ca-PO4nanoparticles and their phase transition to crystalline HAP, as well as control crystal growth rates in specific crystallographic directions, thus changing the classical needle-like morphology of inorganically grown HAP crystals to a biomimetic plate-like morphology.

Published

2020

17. Variations in the Expression Pattern of HSP27and MSK1Genes During the Development of Prehierarchical Follicles in the Zi Geese (Anser Cygnoides)

Author

Sello, Cornelius Tlotliso, Liu, Chang, Lu, Hongtao, Wang, Ziqiu, Msuthwana, Petunia, Tyasi, Thobela Louis, Sun, Yue, Liu, Jing, Xu, Chenguang, Zhou, Yuxuan, Li, Shengyi, Yang, Hui, Sui, Yujian, Hu, Jingtao, and Sun, Yongfeng

Abstract

The p38MAPKs (mitogen-activated protein kinases) signaling contributes a pivotal role in mammalian ovarian follicular development; however, the knowledge regarding their expression in geese remains unresolved. The objective of the current study was to determine the spatio-temporal expression of heat shock protein 27 (HSP27)and mitogen- and stress-activated protein kinase 1 (MSK1) genes in the prehierarchical follicles during geese ovarian development. The prehierarchical follicles samples were harvested from 35- to 37-week-old healthy laying geese. HSP27and MSK1relative expression in various sized prehierachical follicles was detected by real-time quantitative polymerase chain reaction (RT-qPCR) and western blotting. Follicular wall localization of HSP27and MSK1was examined by using immunohistochemistry. Our results at mRNA level indicated that HSP27was highly expressed in middle white follicles whereas MSK1was predominantly expressed in small white follicles. The western blotting results for HSP27and MSK1were inconsistent with the RT-qPCR results in various stages of prehierachical follicular development but noticeably, HSP27proteins were still expressed more in middle white follicles while MSK1proteins were more abundant in primary follicles. At different stages of prehierarchical development, immunodetections in the granulosa and theca cells revealed that HSP27was intensively localized in middle white follicles while strong detections of MSK1were observed in large white follicles. These results indicate HSP27and MSK1might be associated to the key regulators of folliculogenesis in geese.

Published

2020

18. An mRNA-based platform for the delivery of pathogen-specific IgA into mucosal secretions

Author

Deal, Cailin E., Richards, Angelene F., Yeung, Tracy, Maron, Max J., Wang, Ziqiu, Lai, Yen-Ting, Fritz, Brian R., Himansu, Sunny, Narayanan, Elisabeth, Liu, Ding, Koleva, Rositsa, Licht, Stuart, Hsiao, Chiaowen J., Rajlic, Ivana L., Koch, Hillary, Kleyman, Michael, Pulse, Mark E., Weiss, William J., Doering, Jennifer E., Lindberg, Samantha K., Mantis, Nicholas J., Carfi, Andrea, and Plante, Obadiah J.

Abstract

Colonization of the gut and airways by pathogenic bacteria can lead to local tissue destruction and life-threatening systemic infections, especially in immunologically compromised individuals. Here, we describe an mRNA-based platform enabling delivery of pathogen-specific immunoglobulin A (IgA) monoclonal antibodies into mucosal secretions. The platform consists of synthetic mRNA encoding IgA heavy, light, and joining (J) chains, packaged in lipid nanoparticles (LNPs) that express glycosylated, dimeric IgA with functional activity in vitroand in vivo. Importantly, mRNA-derived IgA had a significantly greater serum half-life and a more native glycosylation profile in mice than did a recombinantly produced IgA. Expression of an mRNA encoded Salmonella-specific IgA in mice resulted in intestinal localization and limited Peyer’s patch invasion. The same mRNA-LNP technology was used to express a Pseudomonas-specific IgA that protected from a lung challenge. Leveraging the mRNA antibody technology as a means to intercept bacterial pathogens at mucosal surfaces opens up avenues for prophylactic and therapeutic interventions.

Published

2023

19. Superior Strong and Tough Nacre-Inspired Materials by Interlayer Entanglement

Author

Wang, Lidan, Wang, Bo, Wang, Ziqiu, Huang, Jiajing, Li, Kaiwen, Liu, Senping, Lu, Jiahao, Han, Zhanpo, Gao, Yue, Cai, Gangfeng, Liu, Yingjun, Chen, Yan, Lin, Yue, Liu, Yilun, Gao, Chao, and Xu, Zhen

Abstract

Natural materials teach that mechanical dissipative interactions relieve the conflict between strength and toughness and enable fabrication of strong yet tough artificial materials. Replicating natural nacre structure has yielded rich biomimetic materials; however, stronger interlayer dissipation still waits to be exploited to extend the performance limits of artificial nacre materials. Here, we introduce strong entanglement as a new artificial interlayer dissipative mechanism and fabricate entangled nacre materials with superior strength and toughness, across molecular to nanoscale nacre structures. The entangled graphene nacre fibers achieved high strength of 1.2 GPa and toughness of 47 MJ/m3, and films reached 1.5 GPa and 25 MJ/m3. Experiments and simulations reveal that strong entanglement can effectively dissipate interlayer energy to relieve the conflict between strength and toughness, acting as natural folded proteins. The strong interlayer entanglement opens up a new path for designing stronger and tougher artificial materials to mimic but surpass natural materials.

Published

2023

20. Efficient Electrorheological Technology for Materials, Energy, and Mechanical Engineering: from Mechanisms to Applications

Author

Liang, Yudai, Huang, Dongyang, Zhou, Xuefeng, Wang, Ziqiu, Shi, Quan, Hong, Yaying, Pu, Huayan, Zhang, Mengying, Wu, Jinbo, and Wen, Weijia

Abstract

Electrorheological (ER) technology is an advanced technology based on ER effects. The most common material in ER technology is an electrorheological fluid (ERF), which is a type of smart soft material. The viscosity of ERF is reversibly adjustable by an applied electric field. A new type of electroresponsive soft material, electrorheological elastomer (ERE), which is a derivative of ERFs, has attracted wide attention due to its advantages of not precipitating and easy packaging. ER materials are widely applied in mechanical engineering due to their reversibly tunable characteristics, fast response, and low energy consumption. In addition to basic ER material fabrication and application, ER technology is also used in energy material preparation, oil transportation, and energy storage. The application of ER technology in the energy field provides a good example of the potential applications of ER technology in other fields. This article systematically summarizes the research status and future development prospects of ER technology in materials, energy, and mechanical engineering from the mechanism to application, combined with the latest research results.

Published

2023

21. Isoexergonic Conformations of Surface-Bound Citrate Regulated Bioinspired Apatite Nanocrystal Growth

Author

Wang, Ziqiu, Xu, Zhijun, Zhao, Weilong, Chen, Wei, Miyoshi, Toshikazu, and Sahai, Nita

Abstract

The superior biomechanical properties of bone and dentin are dictated, in part, by the unique plate-like morphology of hydroxyapatite (HAP) nanocrysals within a hierarchically assembled collagen matrix. Understanding the mechanism of crystal growth and thus morphology is important to the rational design of bioinspired apatite nanocrystals for orthopedic and dental applications. Citrate has long been proposed to modulate apatite crystal growth, but major questions exist regarding the HAP-bound citrate conformations and the identities of the interacting functional groups and HAP surface sites. Here, we conducted a comprehensive investigation of the mechanism from the angstrom to submicrometer scale by detailed correlation of the results of high-level metadynamics simulations, employing force-fields benchmarked to experiment and density functional theory calculations with the results of high resolution transmission electron microscopy, nuclear magnetic resonance spectroscopy, solution analysis, and thermogravimetric analysis. Crystal morphology changed from needle- to plate-like with increasing citrate concentration. Citrate adsorbed more strongly on the HAP (100) face than on the (001) face, thus resulting in preferential growth in the [001] direction and the plate-like morphology. Two very different bound conformations were obtained, involving interactions of either one or both terminal carboxyl groups with three or five surface calcium ions, respectively, and a hydrogen bond between the citrate hydroxyl and the HAP surface. Remarkably, despite fewer interaction sites in the single bound carboxyl conformation, the structures were isoexergonic, so both exist at equilibrium. Identification of the former conformation is significant because it allows a greater adsorption density than is traditionally assumed and can help explain concentration-dependence of citrate in modulating crystal morphology. These unique results were enabled first by the application of advanced metadynamics, a technique necessary for the accurate simulation of ionic materials but which is rarely employed in the biomaterials and biomineralization fields and second by the detailed correlation of computational, spectroscopic, and analytical results.

Published

2016

22. c-Met-Akt pathway-mediated enhancement of inhibitory c-Raf phosphorylation is involved in vitamin K1 and sorafenib synergy on HCC growth inhibition

Author

Carr, Brian I., Wang, Ziqiu, Wang, Meifang, Cavallini, Aldo, D’Alessandro, Rosalba, and Refolo, Maria Gratzia

Abstract

Sorafenib is an FDA-approved agent for treatment of human hepatocellular carcinoma (HCC), but tumor shrinkage is minor. We therefore developed a strategy to combine K vitamins with sorafenib to treat HCC, and found that this combination enhanced sorafenib-induced HCC cell growth inhibition. To explore the mechanisms involved, we examined the role of Raf kinase, since both vitamins K and sorafenib were reported to inhibit tumor cell growth via Raf signaling pathway. We found that whereas lower concentration of vitamin K1 (25 μM) or sorafenib (2.5 μM) alone slightly induced c-Raf phosphorylation at both Ser-43 and Ser-259, combination vitamin K1 plus sorafenib resulted in strong c-Raf phosphorylation at these two serine residues. A Raf kinase activity assay confirmed that combination vitamin K1 plus sorafenib had a synergistic inhibitory effect on it. Since c-Raf phosphorylation at Ser-43 and Ser-259 can be regulated by either PKA or Akt kinase, we examined the effects of both vitamin K1 and sorafenib on their phosphorylation. Although vitamin K1 or sorafenib alone induced PKA phosphorylation, no enhanced phosphorylation effects on PKA were found using this combination. However, vitamin K1 enhanced sorafenib-induced c-Met phosphorylation at Tyr-1349, a DEP-1 protein phosphatase acting site, and consequently induced phosphorylation of PI3K-Akt. Both PI3K inhibitor Ly294002 as well as dominate negative Akt plasmid transfection antagonized vitamin K1 plus sorafenib actions on c-Raf phosphorylation and cell growth inhibition, suggesting that c-Met-PI3K-Akt signaling pathway mediated inhibitory c-Raf phosphorylation may play a central role in vitamin K1 plus sorafenib synergy in inhibiting HCC cell growth.

Published

2011

23. K vitamins, PTP antagonism, and cell growth arrest

Author

Carr, Brian I., Wang, Ziqiu, and Kar, Siddhartha

Abstract

The main function of K vitamins is to act as co-factors for γ-glutamyl carboxylase. However, they have also recently been shown to inhibit cell growth. We have chemically synthesized a series of K vitamin analogs with various side chains at the 2 or 3 position of the core naphthoquinone structure. The analogs with short thio-ethanol side chains are found to be more potent growth inhibitors in vitro of various tumor cell lines. Cpd 5 or [2-(2-mercaptoethanol)-3-methyl-1,4-naphthoquinone] is one of the most potent. The anti-proliferation activity of these compounds is antagonized by exogenous thiols but not by non-thiol antioxidants. This suggests that the growth inhibition is mediated by sulfhydryl arylation of cellular glutathione and cysteine-containing proteins and not by oxidative stress. The protein tyrosine phosphatases (PTP) are an important group of proteins that contain cysteine at their catalytic site. PTPs regulate mitogenic signal transduction and cell cycle progression. PTP inhibition by Cpd 5 results in prolonged tyrosine phosphorylation and activation of several kinases and transcription factors including EGFR, ERK1/2, and Elk1. Cpd 5 could activate ERK1/2 either by signaling from an activated EGFR, which is upstream in the signaling cascade, or by direct inhibition of ERK1/2 phosphatase(s). Prolonged ERK1/2 phosphorylation strongly correlates with Cpd 5-mediated growth inhibition. Cpd 5 can also bind to and inhibit the Cdc25 family of dual specific phosphatases. As a result, several Cdc25 substrates (Cdk1, Cdk2, Cdk4) involved in cell cycle progression are tyrosine phosphorylated and thereby inhibited by its action. Cpd 5 could also inhibit both normal liver regeneration and hepatoma growth in vivo. DNA synthesis during rat liver regeneration following partial hepatectomy, transplantable rat hepatoma cell growth, and glutathione-S-transferase-pi expressing hepatocytes after administration of the chemical carcinogen diethylnitrosamine, are all inhibited by Cpd 5 administration. The growth inhibitory effect during liver regeneration and transplantable tumor growth is also correlated with ERK1/2 phosphorylation induced by Cpd 5. Thus, Cpd 5-mediated inhibition of PTPs, such as Cdc25 leads to cell growth arrest due to altered activity of key cellular kinases involved in signal transduction and cell cycle progression. This prototype K vitamin analog represents a novel class of growth inhibitor based upon its action as a selective PTP antagonist. It is clearly associated with prolonged ERK1/2 phosphorylation, which is in contrast with the transient ERK1/2 phosphorylation induced by growth stimulatory mitogens. © 2002 Wiley-Liss, Inc.

Published

2002

24. Identification of Epidermal Growth Factor Receptor as a Target of Cdc25A Protein Phosphatase*

Author

Wang, Ziqiu, Wang, Meifang, Lazo, John S., and Carr, Brian I.

Abstract

Cdc25A, a dual-specificity protein phosphatase, plays a critical role in cell cycle progression. Although cyclin-dependent kinases are established substrates, Cdc25A may also affect other proteins. We have shown here that Cdc25A interacts with epidermal growth factor receptor (EGFR) both physically and functionally in Hep3B human hepatoma cells. Cdc25A inhibitor Cpd 5, a vitamin K analog, inhibited Cdc25A activity in the Cdc25A-EGFR immunocomplex and consequently caused prolonged EGFR tyrosine phosphorylation. Both purified GST-Cdc25A protein and endogenous Hep3B cellular Cdc25A dephosphorylated tyrosine-phosphorylated EGFR, and Cpd 5 antagonized the phosphatase activity of Cdc25A. A functional Cdc25A-EGFR interaction was seen in NR-6 fibroblasts expressing ectopic EGFR but not with a receptor lacking the C terminus or a mutated kinase domain. These data link the cell cycle control Cdc25A phosphatase to an EGFR-linked mitogenic signaling pathway specifically involving EGFR dephosphorylation.

Published

2002

25. Involvement of hepatocyte epidermal growth factor receptor mediated activation of mitogen-activated protein kinase signaling pathways in response to growth inhibition by a novel K vitamin

Author

Wang, Ziqiu, Wang, Meifang, and Carr, Brian I.

Abstract

Compound 5 (Cpd 5), a synthetic K vitamin analogue, or 2-(2-mercaptoethanol)-3-methyl-1,4-naphthoquinone, is a potent inhibitor of epidermal growth factor (EGF)-induced rat hepatocyte DNA synthesis and induces EGF receptor (EGFR) tyrosine phosphorylation. To understand the cellular responses to Cpd 5, its effects on the EGF signal transduction pathway were examined and compared to those of the stimulant, EGF. Cpd 5 induced a cellular response program that included the induction of EGFR tyrosine phosphorylation and the activation of the mitogen-activated protein kinase (MAPK) cascade. EGFR tyrosine phosphorylation was induced by Cpd 5 in a time- and dose-dependent manner. Coimmunoprecipitation studies demonstrated that both EGF and Cpd 5 induced tyrosine phosphorylation of EGFR was associated with increased amounts of adapter proteins Shc and Grb2, and the Ras GTP-GDP exchange protein Sos, indicating the formation of functional EGFR complexes. Although EGFR phosphorylation was induced both by the stimulant EGF and the inhibitor Cpd 5, the timing and intensity of activation by EGF and Cpd 5 were different. EGF activated EGFR transiently, whereas Cpd 5 induced an intense and sustained activation. Cpd 5-altered cells had a decreased ability to dephosphorylate tyrosine phosphorylated EGFR, providing evidence for an inhibition of tyrosine phosphatase activity. Both EGF and Cpd 5 caused an induction of phospho-extracellular response kinase (ERK), which was also more sustained with Cpd 5. Moreover, whereas Cpd 5 induced a striking translocation of phosphorylated ERK from cytosol to the nucleus, no significant nuclear translocation occurred after stimulation with EGF. The data suggest that this novel compound causes growth inhibition through antagonism of EGFR phosphatases and consequent induction of EGFR and ERK phosphorylation. This is supported by experiments with PD 153035 and PD 098059, antagonists of phosphorylation of EGFR and MAP kinase kinase (MEK), respectively, which both antagonized Cpd 5-induced phosphorylation and the inhibition of DNA synthesis. These results imply a mechanism of cell growth inhibition associated with intense and prolonged protein tyrosine phosphorylation. Protein tyrosine phosphatases may thus be a novel target for drugs designed to inhibit cell growth. J. Cell. Physiol. 183:338–346, 2000. © 2000 Wiley-Liss, Inc.

Published

2000

26. M1758 Naturally Occurring K Vitamins Inhibit Pancreatic Cancer Cell Line Growth.

Author

Showalter, Shayna L., Wang, Ziqiu, Costantino, Christina L., Witkiewicz, Agnes, Yeo, Charles J., Brody, Jonathan R., and Carr, Brian I.

Published

2009