The broadly neutralizing human monoclonal antibody 2G12 binds to a carbohydrate-dependent epitope involving three major potential N-linked glycosylation sites (PNGS) of gp120 (N295, N332, and N392). Through analysis of the sensitivity to 2G12 of pseudotyped viruses carrying envelope proteins from HIV-1 clade B-infected long-term nonprogressors, we selected two naturally occurring env clones with opposite sensitivities to 2G12, albeit harboring the 3 particular PNGS known to be essential for 2G12 binding (N295, N332, and N392). The resistant clone presented a long and potentially heavily glycosylated V1V2 loop and an additional PNGS (N302) in the V3 loop. The sensitive clone harbored a short V1V2 loop and lacked the PNGS at N302. We created chimeric envelope genes by swapping the V1V2 domains of the two env clones. The influence of N302 on 2G12 sensitivity was assessed by PCR-based site-directed mutagenesis. Both the exchange of the V1V2 domain and the introduction of the PNGS at N302 on the 2G12-sensitive clone induced a significant decrease in sensitivity to 2G12. In contrast, the reverse V1V2 exchange and the removal of the PNGS at N302 on the 2G12-resistant clone increased sensitivity to 2G12, confirming the influence of these regions on 2G12 sensitivity. Our results, supported by a molecular-modeling study, suggest that both the V1V2 loop and an additional PNGS in V3 might limit access to the 2G12 epitope.