Fuel cell and fuel cell system

1 . A fuel cell, comprising: a polymer electrolyte membrane; an anode electrode on a first side of the polymer electrolyte membrane; a cathode electrode on a second side of the polymer electrolyte membrane; an anode gas diffusion layer on a side of the anode electrode that faces away from the polymer electrolyte membrane; a cathode gas diffusion layer on a side of the cathode electrode that faces away from the polymer electrolyte membrane; an anode flow field plate having an anode flow field for distributing an anode reactant on a side of the anode gas diffusion layer that faces away from the polymer electrolyte membrane; a cathode flow field plate having a cathode flow field for distributing a cathode reactant on a side of the cathode gas diffusion layer that faces away from the polymer electrolyte membrane; and at least one conducting line formed from a hygroscopic and/or capillary-active material for conducting water and thus for moistening the polymer electrolyte membrane. 2 . The fuel cell according to claim 1 , wherein the at least one conducting line is aligned parallel to or identical to a reactant channel of the flow field. 3 . The fuel cell according to claim 1 , wherein the at least one conducting line extends perpendicular to a reactant channel of the flow field. 4 . The fuel cell according to claim 1 , wherein the at least one conducting line is embedded in the polymer electrolyte membrane. 5 . The fuel cell according to claim 1 , wherein the at least one conducting line is embedded in the gas diffusion layer. 6 . The fuel cell according to claim 5 , wherein the at least one conducting line extends along a flow field web separating two reactant channels of the flow field from each other. 7 . The fuel cell according to claim 6 , wherein the dimensions of the at least one conducting line are adapted to the dimensions of the flow field web. 8 . The fuel cell according to claim 1 , wherein the at least one conducting line is connected in a fluid-mechanical manner to a reactant outlet. 9 . The fuel cell according to claim 1 , wherein the at least one conducting line is connected in a fluid-mechanical manner to an outlet of a water extractor arranged in an anode exhaust line. 10 . A fuel cell system comprising a plurality of fuel cells connected in series, each of the fuel cells comprising: a polymer electrolyte membrane; an anode electrode on a first side of the polymer electrolyte membrane; a cathode electrode on a second side of the polymer electrolyte membrane; an anode gas diffusion layer on a side of the anode electrode that faces away from the polymer electrolyte membrane; a cathode gas diffusion layer on a side of the cathode electrode that faces away from the polymer electrolyte membrane; an anode flow field plate having an anode flow field for distributing an anode reactant on a side of the anode gas diffusion layer that faces away from the polymer electrolyte membrane; a cathode flow field plate having a cathode flow field for distributing a cathode reactant on a side of the cathode gas diffusion layer that faces away from the polymer electrolyte membrane; and at least one conducting line formed from a hygroscopic and/or capillary-active material for conducting water and thus for moistening the polymer electrolyte membrane.