We study low energy implications of F-theory GUT models based on SU(5) extended by a $$U(1)'$$ $U{\left(1\right)}^{\prime }$ symmetry which couples non-universally to the three families of quarks and leptons. This gauge group arises naturally from the maximal exceptional gauge symmetry of an elliptically fibred internal space, at a single point of enhancement, $$E_8\supset SU(5)\times SU(5)'\supset SU(5)\times U(1)^4.$$ $E_8\supset SU\left(5\right)\times SU{\left(5\right)}^{\prime }\supset SU\left(5\right)\times U{\left(1\right)}^4.$ Rank-one fermion mass textures and a tree-level top quark coupling are guaranteed by imposing a $$Z_2$$ $Z_2$ monodromy group which identifies two abelian factors of the above breaking sequence. The $$U(1)'$$ $U{\left(1\right)}^{\prime }$ factor of the gauge symmetry is an anomaly free linear combination of the three remaining abelian symmetries left over by $$Z_2$$ $Z_2$ . Several classes of models are obtained, distinguished with respect to the $$U(1)'$$ $U{\left(1\right)}^{\prime }$ charges of the representations, and possible extra zero modes coming in vector-like representations. The predictions of these models are investigated and are compared with the LHC results and other related experiments. Particular cases interpreting the B-meson anomalies observed in LHCb and BaBar experiments are also discussed.