Adeno-associated virus (AAV)-based vectors have emerged as an effective and widely used technology for somatic gene therapy approaches, including those targeting the retina. A major advantage of the AAV technology is the availability of a large number of serotypes that have either been isolated from nature or produced in the laboratory. These serotypes have different properties in terms of sensitivity to neutralizing antibodies, cellular transduction profile and efficiency. The infectivity of AAV vectors depends on the affinity to certain molecules on the cell surface, in particular to cellular glycosaminoglycans (GAGs) such as heparan sulfate proteoglycans (HSPGs). Here, we tested how altering HSPG affinity in AAV vectors affects cellular tropism and transduction efficiency. The previously developed AAV2.GL variant was used as a starting variant to alter or disrupt HSPG affinity. The HSPG-independent AAV9 serotype was used to introduce different HSPG-binding sites. As an indicator of HSPG affinity, we measured the binding strength of the vector variant on a heparin chromatography column. We show that modification of capsid-exposed residues has a strong impact on HSPG affinity, cellular tropism and transduction efficiency in HeLa cells and in vivo in mouse retina. Our study shows that key properties of AAV vectors can be tailored in different directions and used to improve tropism and efficiency.