Eber, Fabian

Eber, Fabian

Prof. Dr. rer. nat. 
Molekulare Biotechnologie, Biochemie, Rechtliche Grundlagen der Biotechnologie, Bioanalytik, Einführung Biotechnologie, Zellkulturtechnik, Biologie
  • Room: B255
  • Badstraße 24, 77652 Offenburg

Function

  • Bachelorstudiengang Biotechnologie BT, Professor
  • Department of Mechanical and Process Engineering (M+V), Professor
  • Bachelorstudiengang Biotechnologie BT, Dean
  • Bachelorstudiengang Biotechnologie BT, Head of Study Program
  • Bachelorstudiengang Biotechnologie BT, Dean of the Bachelor Degree Programs

Research Interests

Research Projects

Resorbable Molybdenum Implants for Patient Individual Craniomaxillofacial Therapy (MOLY-IMPACT) - biologische Testung / in vitro Toxikologie

Patents

M. Thran, A. Thess, F. J. Eber, und B. Dipankar, „Method of reducing the immunostimulatory properties of in vitro transcribed RNA“, WO2022162027A2, 4. August 2022
 
K. Raptoupoulou, F. J. Eber, A. Wochner, und J. N. Kiebel, „Purification and/or formulation of RNA“, WO2018141371, 9. August 2018
 
F. J. Eber, A. Wochner, und T. Roos, „RNA analysis by total hydrolysis“, WO2017149139A1, 8. September 2017
 
A. Wochner, T. Roos, F. J. Eber, und P. Hofmann, „Method for analyzing RNA“, WO2017137095, 17. August 2017
 
I. Reichert, F. J. Eber, C. Mayer, und A. Wochner, „Automated method for isolation, selection and/or detection of microorganisms or cells comprised in a solution“, WO2017064146, 20. April 2017
 
A. Schmid, I. Strobel, und F. J. Eber, „Process for the in vivo production of RNA in a host cell“, WO2017025120, 16. Februar 2017
 
F. J. Eber, S. Sewing, und W. Wagner, „Method of producing RNA from circular DNA and corresponding template DNA“, WO2017009376, 19. Januar 2017
 
A. Wochner und F. J. Eber, „Method for analysis of an RNA molecule“, WO2017001058, 5. Januar 2017
 
F. J. Eber u. a., „Dry power composition compositing long-chain RNA“, WO2016184576, 24. November 2016
 
T. Mutzke u. a., „Method for producing RNA compositions“, WO2016165825, 20. Oktober 2016

Publication

Books Contributions

Wege, C. & Eber, F. J. Bottom-Up Assembly of TMV-Based Nucleoprotein Architectures on Solid Supports. in Virus-Derived Nanoparticles for Advanced Technologies (eds. Wege, C. & Lomonossoff, G. P.) vol. 1776 169–186 (Springer New York, New York, NY, 2018). 

Wege, C. et al. Plant viral nanoscale biotemplates: From virowires to dumbbells and arrays. in Nanotechnology - Fundamentals and Applications of Functional Nanostructures (eds. Schimmel, T., Löhneysen, H. von & Barczewski, M.) 385–409 (Baden-Württemberg-Stiftung, 2012).

Wege, C. et al. Functionality-on-a-stick: complex self-assembling virus derivatives – fabrication, activation and integration into technical environments. in Advances in nanotechnology - physics, chemistry, and biology of functional nanostructures (eds. Schimmel, T., Löhneysen, H. von & Barczewski, M.) 97–126 (2012).

Reviewed Papers

Wendlandt, T. et al. Getting Hold of the Tobamovirus Particle—Why and How? Purification Routes over Time and a New Customizable Approach. Viruses 16, 884 (2024).

Wendlandt, T. et al. Facile Purification and Use of Tobamoviral Nanocarriers for Antibody-Mediated Display of a Two-Enzyme System. Viruses 15, 1951 (2023).

Koch, C. et al. Novel roles for well-known players: from tobacco mosaic virus pests to enzymatically active assemblies. Beilstein J. Nanotechnol. 7, 613–629 (2016).

Schneider, A. et al. Dynamic DNA-controlled ”stop-and-go” assembly of well-defined protein domains on RNA-scaffolded TMV-like nanotubes. Nanoscale 8, 19853–19866 (2016).

Koch, C. et al. Modified TMV Particles as Beneficial Scaffolds to Present Sensor Enzymes. Front. Plant Sci. 6, (2015).

Shukla, S. et al. The Impact of Aspect Ratio on the Biodistribution and Tumor Homing of Rigid Soft-Matter Nanorods. Adv. Healthcare Mater. 4, 874–882 (2015). 

Eber, F. J., Eiben, S., Jeske, H. & Wege, C. RNA-controlled assembly of tobacco mosaic virus-derived complex structures: from nanoboomerangs to tetrapods. Nanoscale 7, 344–355 (2015).

Eiben, S. et al. Tailoring the surface properties of tobacco mosaic virions by the integration of bacterially expressed mutant coat protein. Virus Research 180, 92–96 (2014).

Eber, F. J., Eiben, S., Jeske, H. & Wege, C. Bottom-Up-Assembled Nanostar Colloids of Gold Cores and Tubes Derived From Tobacco Mosaic Virus. Angew. Chem. Int. Ed. 52, 7203–7207 (2013). Said, H. et al. M1.3 – a small scaffold for DNA origami. Nanoscale 5, 284–290 (2013).

Geiger, F. C. et al. TMV nanorods with programmed longitudinal domains of differently addressable coat proteins. Nanoscale 5, 3808 (2013).

Azucena, C. et al. New Approaches for Bottom-Up Assembly of Tobacco Mosaic Virus-Derived Nucleoprotein Tubes on Defined Patterns on Silica- and Polymer-Based Substrates. Langmuir 28, 14867–14877 (2012).

Mueller, A. et al. Inducible Site-Selective Bottom-Up Assembly of Virus-Derived Nanotube Arrays on RNA-Equipped Wafers. ACS Nano 5, 4512–4520 (2011).