Your search keyword '"Farzan, M."' showing total 8 results

1. SARS-CoV-2 entry factors are highly expressed in nasal epithelial cells together with innate immune genes

Author

Sungnak, W., Huang, N., Bécavin, C., Berg, M., Queen, R., Litvinukova, M., Talavera-López, C., Maatz, H., Reichart, D., Sampaziotis, F., Worlock, K. B., Yoshida, M., Barnes, J. L., Banovich, N. E., Barbry, P., Brazma, A., Collin, J., Desai, T. J., Duong, T. E., Eickelberg, O., Falk, C., Farzan, M., Glass, I., Gupta, R. K., Haniffa, M., Horvath, P., Hubner, N., Hung, D., Kaminski, N., Krasnow, M., Kropski, J. A., Kuhnemund, M., Lako, M., Lee, H., Leroy, S., Linnarson, S., Lundeberg, Joakim, Meyer, K. B., Miao, Z., Misharin, A. V., Nawijn, M. C., Nikolic, M. Z., Noseda, M., Ordovas-Montanes, J., Oudit, G. Y., Pe’er, D., Powell, J., Quake, S., Rajagopal, J., Tata, P. R., Rawlins, E. L., Regev, A., Reyfman, P. A., Rozenblatt-Rosen, O., Saeb-Parsy, K., Samakovlis, Christos, Schiller, H. B., Schultze, J. L., Seibold, M. A., Seidman, C. E., Seidman, J. G., Shalek, A. K., Shepherd, D., Spence, J., Spira, A., Sun, X., Teichmann, S. A., Theis, F. J., Tsankov, A. M., Vallier, L., van den Berge, M., Whitsett, J., Xavier, R., Xu, Y., Zaragosi, L. -E, Zerti, D., Zhang, H., Zhang, K., Rojas, M., Figueiredo, F., Network, HCA Lung Biological, Sungnak, W., Huang, N., Bécavin, C., Berg, M., Queen, R., Litvinukova, M., Talavera-López, C., Maatz, H., Reichart, D., Sampaziotis, F., Worlock, K. B., Yoshida, M., Barnes, J. L., Banovich, N. E., Barbry, P., Brazma, A., Collin, J., Desai, T. J., Duong, T. E., Eickelberg, O., Falk, C., Farzan, M., Glass, I., Gupta, R. K., Haniffa, M., Horvath, P., Hubner, N., Hung, D., Kaminski, N., Krasnow, M., Kropski, J. A., Kuhnemund, M., Lako, M., Lee, H., Leroy, S., Linnarson, S., Lundeberg, Joakim, Meyer, K. B., Miao, Z., Misharin, A. V., Nawijn, M. C., Nikolic, M. Z., Noseda, M., Ordovas-Montanes, J., Oudit, G. Y., Pe’er, D., Powell, J., Quake, S., Rajagopal, J., Tata, P. R., Rawlins, E. L., Regev, A., Reyfman, P. A., Rozenblatt-Rosen, O., Saeb-Parsy, K., Samakovlis, Christos, Schiller, H. B., Schultze, J. L., Seibold, M. A., Seidman, C. E., Seidman, J. G., Shalek, A. K., Shepherd, D., Spence, J., Spira, A., Sun, X., Teichmann, S. A., Theis, F. J., Tsankov, A. M., Vallier, L., van den Berge, M., Whitsett, J., Xavier, R., Xu, Y., Zaragosi, L. -E, Zerti, D., Zhang, H., Zhang, K., Rojas, M., Figueiredo, F., and Network, HCA Lung Biological

Abstract

We investigated SARS-CoV-2 potential tropism by surveying expression of viral entry-associated genes in single-cell RNA-sequencing data from multiple tissues from healthy human donors. We co-detected these transcripts in specific respiratory, corneal and intestinal epithelial cells, potentially explaining the high efficiency of SARS-CoV-2 transmission. These genes are co-expressed in nasal epithelial cells with genes involved in innate immunity, highlighting the cells’ potential role in initial viral infection, spread and clearance. The study offers a useful resource for further lines of inquiry with valuable clinical samples from COVID-19 patients and we provide our data in a comprehensive, open and user-friendly fashion at www.covid19cellatlas.org., QC 20200625

Published

2020

2. Lectin-Dependent Enhancement of Ebola Virus Infection via Soluble and Transmembrane C-type Lectin Receptors

Author

Schneider, BS, Brudner, M, Karpel, M, Lear, C, Chen, L, Yantosca, LM, Scully, C, Sarraju, A, Sokolovska, A, Zariffard, MR, Eisen, DP, Mungall, BA, Kotton, DN, Omari, A, Huang, I-C, Farzan, M, Takahashi, K, Stuart, L, Stahl, GL, Ezekowitz, AB, Spear, GT, Olinger, GG, Schmidt, EV, Michelow, IC, Schneider, BS, Brudner, M, Karpel, M, Lear, C, Chen, L, Yantosca, LM, Scully, C, Sarraju, A, Sokolovska, A, Zariffard, MR, Eisen, DP, Mungall, BA, Kotton, DN, Omari, A, Huang, I-C, Farzan, M, Takahashi, K, Stuart, L, Stahl, GL, Ezekowitz, AB, Spear, GT, Olinger, GG, Schmidt, EV, and Michelow, IC

Abstract

Mannose-binding lectin (MBL) is a key soluble effector of the innate immune system that recognizes pathogen-specific surface glycans. Surprisingly, low-producing MBL genetic variants that may predispose children and immunocompromised individuals to infectious diseases are more common than would be expected in human populations. Since certain immune defense molecules, such as immunoglobulins, can be exploited by invasive pathogens, we hypothesized that MBL might also enhance infections in some circumstances. Consequently, the low and intermediate MBL levels commonly found in human populations might be the result of balancing selection. Using model infection systems with pseudotyped and authentic glycosylated viruses, we demonstrated that MBL indeed enhances infection of Ebola, Hendra, Nipah and West Nile viruses in low complement conditions. Mechanistic studies with Ebola virus (EBOV) glycoprotein pseudotyped lentiviruses confirmed that MBL binds to N-linked glycan epitopes on viral surfaces in a specific manner via the MBL carbohydrate recognition domain, which is necessary for enhanced infection. MBL mediates lipid-raft-dependent macropinocytosis of EBOV via a pathway that appears to require less actin or early endosomal processing compared with the filovirus canonical endocytic pathway. Using a validated RNA interference screen, we identified C1QBP (gC1qR) as a candidate surface receptor that mediates MBL-dependent enhancement of EBOV infection. We also identified dectin-2 (CLEC6A) as a potentially novel candidate attachment factor for EBOV. Our findings support the concept of an innate immune haplotype that represents critical interactions between MBL and complement component C4 genes and that may modify susceptibility or resistance to certain glycosylated pathogens. Therefore, higher levels of native or exogenous MBL could be deleterious in the setting of relative hypocomplementemia which can occur genetically or because of immunodepletion during active infectio

Published

2013

3. H. SARS-CoV, but not HCoV-NL63, utilizes cathepsins to infect cells: viral entry

Author

Huang, I.C., Bosch, B.J., Li, W., Farzan, M., Rottier, P.J.M., Choe, H., Huang, I.C., Bosch, B.J., Li, W., Farzan, M., Rottier, P.J.M., and Choe, H.

Published

2006

4. H. SARS-CoV, but not HCoV-NL63, utilizes cathepsins to infect cells: viral entry

Author

Strategic Infection Biology, Dep Infectieziekten Immunologie, Huang, I.C., Bosch, B.J., Li, W., Farzan, M., Rottier, P.J.M., Choe, H., Strategic Infection Biology, Dep Infectieziekten Immunologie, Huang, I.C., Bosch, B.J., Li, W., Farzan, M., Rottier, P.J.M., and Choe, H.

Published

2006

5. H. SARS-CoV, but not HCoV-NL63, utilizes cathepsins to infect cells: viral entry

Author

Strategic Infection Biology, Dep Infectieziekten Immunologie, Huang, I.C., Bosch, B.J., Li, W., Farzan, M., Rottier, P.J.M., Choe, H., Strategic Infection Biology, Dep Infectieziekten Immunologie, Huang, I.C., Bosch, B.J., Li, W., Farzan, M., Rottier, P.J.M., and Choe, H.

Published

2006

6. H. SARS-CoV, but not HCoV-NL63, utilizes cathepsins to infect cells: viral entry

Author

Strategic Infection Biology, Dep Infectieziekten Immunologie, Huang, I.C., Bosch, B.J., Li, W., Farzan, M., Rottier, P.J.M., Choe, H., Strategic Infection Biology, Dep Infectieziekten Immunologie, Huang, I.C., Bosch, B.J., Li, W., Farzan, M., Rottier, P.J.M., and Choe, H.

Published

2006

7. SARS-CoV receptor

Author

Li, W, Lee, K, Wong, S, Moore, M, Vasilieva, N, Greenough, TC, Farzan, M, Choe, H, Li, W, Lee, K, Wong, S, Moore, M, Vasilieva, N, Greenough, TC, Farzan, M, and Choe, H

Published

2004

8. SARS-CoV receptor

Author

Li, W, Lee, K, Wong, S, Moore, M, Vasilieva, N, Greenough, TC, Farzan, M, Choe, H, Li, W, Lee, K, Wong, S, Moore, M, Vasilieva, N, Greenough, TC, Farzan, M, and Choe, H

Published

2004