When irradiated, purple membrane from Halobacterium halobium oriented in a polyacrylamide gel produces a photocurrent. The correlation of the microsecond component (B2) of the photocurrent with the L-M optical transition was studied. It was found that the lifetimes of B2 and the L-M transition are identical over the entire pH range from 2.4 to 11.0 when measured in high salt (>5 mM CaCl(2) or >40 mM KCl). Changing the temperature from 10 to 35 degrees C, or replacing the H(2)O with D(2)O maintains this correlation. The amplitude of B2 and the L-M transition are also correlated over the pH range where both of them can be represented as a single exponential. At high pH (>8), three exponentials were required to fit both the optical and photocurrent signals. Two of them are the previously described fast and slow components of M formation, but a new intermediate with a very fast lifetime, 0.3 mus, was observed both in absorption (lambda = 410 nm) and photocurrent measurements. The lifetimes of all three were found to be pH independent. This would exclude models for the L to M portion of the photocycle that explained its complex pH-dependent behavior as being due to a single pH-dependent rate constant. The area of B2, which is proportional to the number and the distance the charge moved during the transition, is almost constant from pH 5.0 to pH 8.0. It decreases to almost zero at pH 2.0 and pH 10.6 with pKs at 2.8 and 9.1. Because B2 is thought to normally reflect proton release from the membrane, this suggests at very low and high pH the photocycle does not pump protons. The pK at high pHs for the formation of the nonpumping photocycle is probably related to the formation of a new photocycle featuring the fast rising form of M.