The uniaxial extensional-flow data of Huang and co-workers [ACS Macro Lett. 2013, 2, 741; J. Rheol. 2016, 60, 465] on several polystyrene systems, both melts and solutions, are here successfully compared-With the predictions of a recent model [Ianniruberto, Macromolecules 2015, 48,, 6306] that accounts for flow-induced friction-coefficient reduction. The model is here effectively simplified without loss of accuracy. Comparison with the solution data of Huang et al. [ACS Macro Lett. 2013, 2, 741], only differing for the size of the oligorneric solvent (from nearly pile Kuhn length up to a few ones), reveals that friction reduction must include oligorner-size-dependent orientational coupling between the oligomeric solvent and the polymer molecules, such interactions vanishing for the smallest oligomer. The theological "measure" of this nematic-interaction as a function of the oligomer size (for small oligomers) is the novel result of the present-paper, together with a further confirmation of the importance of friction coefficient reduction in strongly aligning flows. The model is also used to describe the stress relaxation data following fast uniaxial extension recently reported by Huang and Rasmussen [J. Rheol. 2016, 60, 465], confirming that the short-time relaxation process occurs at 4 faster rate because of the friction coefficient reduction induced by the previous flow. Those data also reveal the key role of convective constraint release induced by chain retraction, similarly to what happens in relaxation experiments following a large step strain.