Improved targeting of human CD4+ T cells by nanobody-modified AAV2 gene therapy vectors.

Martin V Hamann,Ilona Hauber,Bjoern Traenkle,Ulrich Rothbauer,Niklas Beschorner,Carola Schneider,Philipp D Kaiser,Ulrike C Lange,Joachim Hauber,Daniel Foth,Xuan-Khang Vu,Hildegard Büning,Chen Ling

doi:10.1371/journal.pone.0261269

Abstract

Adeno-associated viruses (AAV) are considered non-pathogenic in humans, and thus have been developed into powerful vector platforms for in vivo gene therapy. Although the various AAV serotypes display broad tropism, frequently infecting multiple tissues and cell types, vectors for specific and efficient targeting of human CD4+ T lymphocytes are largely missing. In fact, a substantial translational bottleneck exists in the field of therapeutic gene transfer that would require in vivo delivery into peripheral disease-related lymphocytes for subsequent genome editing. To solve this issue, capsid modification for retargeting AAV tropism, and in turn improving vector potency, is considered a promising strategy. Here, we genetically modified the minor AAV2 capsid proteins, VP1 and VP2, with a set of novel nanobodies with high-affinity for the human CD4 receptor. These novel vector variants demonstrated improved targeting of human CD4+ cells, including primary human peripheral blood mononuclear cells (PBMC) and purified human CD4+ T lymphocytes. Thus, the technical approach presented here provides a promising strategy for developing specific gene therapy vectors, particularly targeting disease-related peripheral blood CD4+ leukocytes.

Highlights

Adeno-associated virus (AAV)-derived vectors have become a leading gene delivery tool in clinical gene therapies, especially when direct therapeutic gene transfer is needed [1,2,3]
Gene therapy vectors based on AAV have become one of the leading delivery tools in human clinical gene therapy trials [2, 8, 9, 14]
Therapeutic gene transfer into human disease-associated leukocytes would greatly benefit from the availability of such novel AAV vector constructs

Summary

Introduction

Adeno-associated virus (AAV)-derived vectors have become a leading gene delivery tool in clinical gene therapies, especially when direct (i.e. in vivo) therapeutic gene transfer is needed [1,2,3]. AAV is a dependoparvovirus, considered to be non-pathogenic in humans. AAV consists of a non-enveloped, icosahedral capsid of ~25 nm and a ~4.7 kb single-stranded DNA genome [4]. The viral genome is flanked by two inverted terminal repeat (ITR) elements, which function as origin of replication and the packaging signal [5, 6].

Methods

Results

Conclusion