Jpm. Schelvis et al., RESONANCE RAMAN CHARACTERIZATION OF THE HEME DOMAIN OF SOLUBLE GUANYLATE-CYCLASE, Biochemistry (Easton), 37(46), 1998, pp. 16289-16297
report the resonance Raman characterization of the heme domain of rat
lung soluble guanylate cyclase (sGC) expressed in Escherichia coli. Li
ke heterodimeric sGC isolated from bovine lung, the sGC heme domain [b
eta 1(1-385)] and its heme ligand mutant H105G(Lm) contain a stoichiom
etric amount of heme, which is five-coordinate, high-spin ferrous in b
oth beta 1(1-385) and chemically reduced H105G(Im). In the presence of
NO, both beta 1(1-385) and H105G(lm) form a five-coordinate nitrosyl
heme complex with a nu(Fe-NO) value of 525 cm(-1) and a nu(NO) value o
f 1676 cm(-1). For the first time, the Fe-N-O bending mode near 400 cm
(-1) has been identified in a five-coordinate nitrosyl heme complex. B
oth beta 1(1-385) and H105G(Im) form a six-coordinate, low-spin comple
x with CO. We find evidence for two binding conformations of the Fe-CO
unit. The conformation that is more prevalent in beta 1(1-385) has a
nu(Fe-CO) value of 478 cm(-1) and a delta(Fe-C-O) value of 567 cm(-1),
whereas the dominant conformation in H105G(Im) is characterized by a
nu(Fe-CO) value of 495 cm(-1) and a delta(Fe-C-O) value of 572 cm(-1).
We propose that in the dominant conformation of H105G(Lm)-CO the Fe-C
O unit is hydrogen bonded to a distal residue, while this is not the c
ase in beta 1(1-385). Reexamination of sGC isolated from bovine lung t
issue indicates that it also has two binding conformations for CO; the
more populated form is not hydrogen-bonded. We propose that the absen
ce of hydrogen-bond formation between a distal residue and exogenous l
igands is physiologically relevant in lowering the oxygen affinity of
heterodimeric sGC and, therefore, stabilizing the ferrous, active form
of the enzyme under aerobic conditions.