Abstract
HIV-1 infection is characterized by an ongoing replication leading to T-lymphocyte decline which is paralleled by the switch from CCR5 to CXCR4 coreceptor usage. To predict coreceptor usage, several computer algorithms using gp120 V3 loop sequence data have been developed. In these algorithms an occupation of the V3 positions 11 and 25, by one of the amino acids lysine (K) or arginine (R), is an indicator for CXCR4 usage. Amino acids R and K dominate at these two positions, but can also be identified at positions 9 and 10. Generally, CXCR4-viruses possess V3 sequences, with an overall positive charge higher than the V3 sequences of R5-viruses. The net charge is calculated by subtracting the number of negatively charged amino acids (D, aspartic acid and E, glutamic acid) from the number of positively charged ones (K and R). In contrast to D and E, which are very similar in their polar and acidic properties, the characteristics of the R guanidinium group differ significantly from the K ammonium group. However, in coreceptor predictive computer algorithms R and K are both equally rated. The study was conducted to analyze differences in infectivity and coreceptor usage because of R-to-K mutations at the V3 positions 9, 10 and 11. V3 loop mutants with all possible RRR-to-KKK triplets were constructed and analyzed for coreceptor usage, infectivity and neutralization by SDF-1α and RANTES. Virus mutants R9R10R11 showed the highest infectivity rates, and were inhibited more efficiently in contrast to the K9K10K11 viruses. They also showed higher efficiency in a virus-gp120 paired infection assay. Especially V3 loop position 9 was relevant for a switch to higher infectivity when occupied by R. Thus, K-to-R exchanges play a role for enhanced viral entry efficiency and should therefore be considered when the viral phenotype is predicted based on V3 sequence data.
Highlights
The third variable region (V3 loop) of the HIV-1 envelope protein plays an important role in HIV-1 infection [1,2], being the primary determinant for binding to one of the two 7transmembrane receptors CCR5 (R5-tropic) and CXCR4 (X4-tropic) [3,4]
Effect of Lysine to Arginine Exchanges on HIV-1 Infection the V3 loop amino acid sequence, or even because of a single amino acid mutation within the V3 loop, HIV-1 can shift from the R5- to the X4-tropic phenotype [5] or can develop R5X4dualtropism
The biologically relevant structure of the V3 loop has been identified in its CD4 bound state, the initial steps and their precise mechanism by which the V3 loop binds to CXCR4 or CCR5 is not fully understood as the V3 loop is extremely variable
Summary
The third variable region (V3 loop) of the HIV-1 envelope protein (gp120) plays an important role in HIV-1 infection [1,2], being the primary determinant for binding to one of the two 7transmembrane receptors CCR5 (R5-tropic) and CXCR4 (X4-tropic) [3,4]. It is suggested that binding of gp120 to CD4 initiates a structural change of the gp120 trimer [8] This leads to the exposure of a protruding cluster of three V3 loops all together pointing towards the chemokine receptor [9]. In this state the V3 loop consists of three structural elements. A sequence variable and highly flexible stem region and thirdly, a conserved turn-motif forming the tip of the V3 loop [1]
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