With limited reductant and nitrite under anaerobic conditions, copper-containing nitrite reductase (NiR) of Rhodobacter sphaeroides yielded endogenous NO and the Cu(I)NO derivative of NiR. N-14- and N-15-nitrite substrates gave rise to characteristic (NO)-N-14 and (NO)-N-15 EPR hyperfine features indicating NO involvement, and enrichment of NiR with Cu-63 isotope caused an EPR line shape change showing copper involvement. A markedly similar Cu(I)NONiR complex was made by anaerobically adding a little endogenous NO gas to reduced protein and immediately freezing. The Cu(I) NONiR signal accounted for 60-90% of the integrated EPR intensity formerly associated with the Type 2 catalytic copper. Analysis of NO and Cu hyperfine couplings and comparison to couplings of inorganic Cu(I) NO model systems indicated similar to 50% spin on the N of NO and similar to 17% spin on Cu. ENDOR revealed weak nitrogen hyperfine coupling to one or more likely histidine ligands of copper. Although previous crystallography of the conservative I289V mutant had shown no structural change beyond the 289 position, this mutation, which eliminates the C delta 1 methyl of I289, caused the Cu(I) NONiR EPR spectrum to change and proton ENDOR features to be significantly altered. The proton hyperfine coupling that was significantly altered was consistent with a dipolar interaction between the C delta 1 protons of I289 and electron spin on the NO, where the NO would be located 3.0-3.7 angstrom from these protons. Such a distance positions the NO of Cu(I) NO as an axial ligand to Type 2 Cu(I).