Your search keyword '"single-virus tracking"' showing total 6 results

1. Label-free imaging of virus-cell interactions using 200 Hz ROCS microscopy

Author

Huber Dominik and Rohrbach Alexander

Subjects

rotating-coherent-scattering-microscopy (rocs), single-virus tracking, label-free, Microbiology, QR1-502, Physiology, QP1-981, Zoology, QL1-991

Published

2024

2. Lipid-Specific Labeling of Enveloped Viruses with Quantum Dots for Single-Virus Tracking

Author

Li-Juan Zhang, Shaobo Wang, Li Xia, Cheng Lv, Hong-Wu Tang, Zhenpu Liang, Gengfu Xiao, and Dai-Wen Pang

Subjects

enveloped virus, lipid-specific labeling, quantum dot, single-virus tracking, Microbiology, QR1-502

Abstract

ABSTRACT Quantum dots (QDs) possess optical properties of superbright fluorescence, excellent photostability, narrow emission spectra, and optional colors. Labeled with QDs, single molecules/viruses can be rapidly and continuously imaged for a long time, providing more detailed information than when labeled with other fluorophores. While they are widely used to label proteins in single-molecule-tracking studies, QDs have rarely been used to study virus infection, mainly due to a lack of accepted labeling strategies. Here, we report a general method to mildly and readily label enveloped viruses with QDs. Lipid-biotin conjugates were used to recognize and mark viral lipid membranes, and streptavidin-QD conjugates were used to light them up. Such a method allowed enveloped viruses to be labeled in 2 h with specificity and efficiency up to 99% and 98%, respectively. The intact morphology and the native infectivity of viruses were preserved. With the aid of this QD labeling method, we lit wild-type and mutant Japanese encephalitis viruses up, tracked their infection in living Vero cells, and found that H144A and Q258A substitutions in the envelope protein did not affect the virus intracellular trafficking. The lipid-specific QD labeling method described in this study provides a handy and practical tool to readily “see” the viruses and follow their infection, facilitating the widespread use of single-virus tracking and the uncovering of complex infection mechanisms. IMPORTANCE Virus infection in host cells is a complex process comprising a large number of dynamic molecular events. Single-virus tracking is a versatile technique to study these events. To perform this technique, viruses must be fluorescently labeled to be visible to fluorescence microscopes. The quantum dot is a kind of fluorescent tag that has many unique optical properties. It has been widely used to label proteins in single-molecule-tracking studies but rarely used to study virus infection, mainly due to the lack of an accepted labeling method. In this study, we developed a lipid-specific method to readily, mildly, specifically, and efficiently label enveloped viruses with quantum dots by recognizing viral envelope lipids with lipid-biotin conjugates and recognizing these lipid-biotin conjugates with streptavidin-quantum dot conjugates. It is not only applicable to normal viruses, but also competent to label the key protein-mutated viruses and the inactivated highly virulent viruses, providing a powerful tool for single-virus tracking.

Published

2020

3. Interaction of Bacteriophage l with Its E. coli Receptor, LamB

Author

Sujoy Chatterjee and Eli Rothenberg

Subjects

&#160, bacteriophage, lambda phage, LamB receptor, protein J, single-virus tracking, Microbiology, QR1-502

Abstract

The initial step of viral infection is the binding of a virus onto the host cell surface. This first viral-host interaction would determine subsequent infection steps and the fate of the entire infection process. A basic understating of the underlining mechanism of initial virus-host binding is a prerequisite for establishing the nature of viral infection. Bacteriophage λ and its host Escherichia coli serve as an excellent paradigm for this purpose. λ phages bind to specific receptors, LamB, on the host cell surface during the infection process. The interaction of bacteriophage λ with the LamB receptor has been the topic of many studies, resulting in wealth of information on the structure, biochemical properties and molecular biology of this system. Recently, imaging studies using fluorescently labeled phages and its receptor unveil the role of spatiotemporal dynamics and divulge the importance of stochasticity from hidden variables in the infection outcomes. The scope of this article is to review the present state of research on the interaction of bacteriophage λ and its E. coli receptor, LamB.

Published

2012

4. Autographa Californica Multiple Nucleopolyhedrovirus Enters Host Cells via Clathrin-Mediated Endocytosis and Direct Fusion with the Plasma Membrane

Author

Fujun Qin, Congrui Xu, Chengfeng Lei, Jia Hu, and Xiulian Sun

Subjects

AcMNPV, single-virus tracking, quantitative electron microscopy, clathrin-mediated endocytosis, direct fusion with the plasma membrane, Microbiology, QR1-502

Abstract

The cell entry mechanism of Autographa californica multiple nucleopolyhedrovirus (AcMNPV) is not fully understood. Previous studies showed that AcMNPV entered host cells primarily through clathrin-mediated endocytosis, and could efficiently infect cells via fusion with the plasma membrane after a low-pH trigger. However, whether AcMNPV enters cells via these two pathways simultaneously, and the exact manner in which AcMNPV particles are internalized into cells remains unclear. In this study, using single-virus tracking, we observed that AcMNPV particles were first captured by pre-existing clathrin-coated pits (CCP), and were then delivered to early endosomes. Population-based analysis of single-virus tracking and quantitative electron microscopy demonstrated that the majority of particles were captured by CCPs and internalized via invagination. In contrast, a minority of virus particles were not delivered to CCPs, and were internalized through direct fusion with the plasma membrane without invagination. Quantitative electron microscopy also showed that, while inhibition of CCP assembly significantly impaired viral internalization, inhibition of endosomal acidification blocked virus particles out of vesicles. Collectively, these findings demonstrated that approximately 90% of AcMNPV particles entered cells through clathrin-mediated endocytosis and 10% entered via direct fusion with the plasma membrane. This study will lead toward a better understanding of AcMNPV infection.

Published

2018

5. Dynamic Dissection of the Endocytosis of Porcine Epidemic Diarrhea Coronavirus Cooperatively Mediated by Clathrin and Caveolae as Visualized by Single-Virus Tracking

Author

Yanke Shan, Wei Hou, Yangyang Li, Shouyu Wang, Jian Wang, and Fei Liu

Subjects

Endosome, Swine, viruses, Endocytic cycle, Endocytosis, medicine.disease_cause, Caveolae, Microbiology, Clathrin, porcine epidemic diarrhea coronavirus, Cell Line, Cell membrane, 03 medical and health sciences, endocytic pathway, Virology, Chlorocebus aethiops, medicine, Animals, Vero Cells, 030304 developmental biology, Coronavirus, Swine Diseases, 0303 health sciences, biology, 030306 microbiology, Porcine epidemic diarrhea virus, Cell Membrane, virus diseases, Virus Internalization, biology.organism_classification, QR1-502, Cell biology, medicine.anatomical_structure, endosome trafficking, biology.protein, single-virus tracking, Coronavirus Infections, viral fusion, Research Article

Abstract

Emerging and re-emerging coronaviruses cause serious human and animal epidemics worldwide. For many enveloped viruses, including coronavirus, it is evident that breaking the plasma membrane barrier is a pivotal and complex process, which contains multiple dynamic steps., Coronaviruses (CoVs) have caused severe diseases in humans and animals. Endocytic pathways, such as clathrin-mediated endocytosis (CME) and caveolae-mediated endocytosis (CavME), play an important role for CoVs to penetrate the cell membrane barrier. In this study, a novel CoV entry manner is unraveled in which clathrin and caveolae can cooperatively mediate endocytosis of porcine epidemic diarrhea coronavirus (PEDV). Using multicolor live-cell imaging, the dynamics of the fluorescently labeled clathrin structures, caveolae structures, and PEDV were dissected. During CavME of PEDV, we found that clathrin structures can fuse with caveolae near the cell plasma membrane, and the average time of PEDV penetrating the cell membrane was within ∼3 min, exhibiting a rapid course of PEDV entry. Moreover, based on the dynamic recruitment of clathrin and caveolae structures and viral motility, the direct evidence also shows that about 20% of PEDVs can undergo an abortive entry via CME and CavME. Additionally, the dynamic trafficking of PEDV from clathrin and caveolae structures to early endosomes, and from early endosomes to late endosomes, and viral fusion were directly dissected, and PEDV fusion mainly occurred in late endosomes within ∼6.8 min after the transport of PEDV to late endosomes. Collectively, this work systematically unravels the early steps of PEDV infection, which expands our understanding of the mechanism of CoV infection.

Published

2021

6. Lipid-Specific Labeling of Enveloped Viruses with Quantum Dots for Single-Virus Tracking

Author

Shaobo Wang, Li Xia, Cheng Lv, Hong-Wu Tang, Li-Juan Zhang, Gengfu Xiao, Zhenpu Liang, and Dai-Wen Pang

Subjects

viruses, Virulence, Biotin, 02 engineering and technology, Microbiology, Virus, Host-Microbe Biology, Madin Darby Canine Kidney Cells, 03 medical and health sciences, Membrane Lipids, Dogs, Viral envelope, Virology, Cricetinae, enveloped virus, Chlorocebus aethiops, Quantum Dots, Animals, Vero Cells, 030304 developmental biology, Infectivity, 0303 health sciences, Staining and Labeling, Chemistry, quantum dot, 021001 nanoscience & nanotechnology, Fluorescence, QR1-502, Microscopy, Fluorescence, Quantum dot, lipid-specific labeling, Encephalitis Viruses, Japanese, Biophysics, Vero cell, single-virus tracking, Streptavidin, Single-Cell Analysis, 0210 nano-technology, Fluorescent tag, Research Article

Abstract

Virus infection in host cells is a complex process comprising a large number of dynamic molecular events. Single-virus tracking is a versatile technique to study these events. To perform this technique, viruses must be fluorescently labeled to be visible to fluorescence microscopes. The quantum dot is a kind of fluorescent tag that has many unique optical properties. It has been widely used to label proteins in single-molecule-tracking studies but rarely used to study virus infection, mainly due to the lack of an accepted labeling method. In this study, we developed a lipid-specific method to readily, mildly, specifically, and efficiently label enveloped viruses with quantum dots by recognizing viral envelope lipids with lipid-biotin conjugates and recognizing these lipid-biotin conjugates with streptavidin-quantum dot conjugates. It is not only applicable to normal viruses, but also competent to label the key protein-mutated viruses and the inactivated highly virulent viruses, providing a powerful tool for single-virus tracking., Quantum dots (QDs) possess optical properties of superbright fluorescence, excellent photostability, narrow emission spectra, and optional colors. Labeled with QDs, single molecules/viruses can be rapidly and continuously imaged for a long time, providing more detailed information than when labeled with other fluorophores. While they are widely used to label proteins in single-molecule-tracking studies, QDs have rarely been used to study virus infection, mainly due to a lack of accepted labeling strategies. Here, we report a general method to mildly and readily label enveloped viruses with QDs. Lipid-biotin conjugates were used to recognize and mark viral lipid membranes, and streptavidin-QD conjugates were used to light them up. Such a method allowed enveloped viruses to be labeled in 2 h with specificity and efficiency up to 99% and 98%, respectively. The intact morphology and the native infectivity of viruses were preserved. With the aid of this QD labeling method, we lit wild-type and mutant Japanese encephalitis viruses up, tracked their infection in living Vero cells, and found that H144A and Q258A substitutions in the envelope protein did not affect the virus intracellular trafficking. The lipid-specific QD labeling method described in this study provides a handy and practical tool to readily “see” the viruses and follow their infection, facilitating the widespread use of single-virus tracking and the uncovering of complex infection mechanisms.

Published

2020