Ser-L223 is close to ubiquinone (Q(B)) in the B-branch of the bacterial photosynthetic reaction center (bRC) from Rhodobacter (Rb) sphaeroides. Therefore, the presence of a hydrogen bond (H bond) between the two was naturally proposed from the crystal structure. The hydrogen bonding pattern Of QB from the light-exposed structure was studied by generating hydrogen atom coordinates based on the CHARM force field. In the QB neutral charge state (Q(B)(0)), no H bond was found between the oxygen of the OH group from Ser-L223 and the carbonyl oxygen Of QB that is distal to the non-heme iron. In the reduced state (Q(B)(-)), however, Ser-L213 was found to form an H bond with QB only when Asp-L213 is protonated by more than 0.75 H+. This indicates the significance of the protonation of Asp-L213 in forming an H bond between Ser-L223 and Q(B). We found that the driving force to form the H bond between Ser-L223 and Q(B) is enhanced by the positively charged Arg-L217. The calculated Q(B) redox potentials with or without this H bond discriminated two ET rates, which are close to the faster and slower time phases observed in UV-Vis and FTIR studies. Together with the calculated redox potential of the quinones, this H-bond formation could play a key role in conformational gating for the ET process from Q(A) to Q(B).