Two crystal structures of dehydrated $Ag_{2.8}ZN_{4.6}-A$ and of its ethylene sorption complex have been determined by single-crystal X-ray diffraction techniques. The structures were solved and refined in the cubic space group Pm3m at 23(1)$^{circ}$C. Dehydration of two crystals studied were achieved at 400$^{circ}$C and $2{ imes}10^{-6}$ Torr for 2 days and one crystal was treated with 250 Torr of ethylene at 25(1)$^{circ}$C. The structures of dehydrated $Ag_{2.8}ZN_{4.6}-A$ (a = 12.137(2) ${AA}$ and of its ethylene sorption complex (a = 12.106(2)${AA}$) were refined to final error indices, R(weighted) = 0.044 with 237 reflections and R(weighted) = 0.050 with 301 reflections, respectively, for which I > 3${sigma}$(I). 2.8 $Ag^+$ ions are recessed 0.922(2) ${AA}$ from (111) plane of three 6-ring oxygens into the large cavity where each forms a lateral ${pi}$ complex with an ethylene molecule. These $Ag^+$ ions are in 2.240(5)${AA}$ from three framework oxide ions and 2.290(5) ${AA}$ from each carbon atom of an ethylene molecule. The $Zn^{2+}$ ions occupy two different threefold axis positions of the unit cell. 2.8 $Zn^{2+}$ ions are recessed 0.408(2) ${AA}$ from (111) plane of the 6-ring oxygens and each $Zn^{2+}$ ion forms a $pi$ complex with an $C_2H_4$ molecule. The distances between $Zn^{2+}$ ions and carbon atom of ethylene molecule, Zn(2)-C = 2.78(4) ${AA}$ are long. This indicates that this bond is relatively weak.