Trimethyllysine 72 (Tml72) of yeast iso-1-cytochrome c lies across the surface of the heme crevice loop (Ω-loop D, residues 70-85) like a brace. Lys72 is oriented similarly in horse cytochrome c (Cytc). To determine whether this residue affects the dynamics of opening the heme crevice loop, we have studied the effect of a Tml72 to Ala substitution on the formation of the His79-heme alkaline conformer near neutral pH using a variant of iso-1-Cytc including K72A and K79H mutations. Guanidine hydrochloride denaturation shows that the Tml72 to Ala substitution within error does not affect the global stability of the protein. The effect of the Tml72 to Ala substitution on the thermodynamics of the His79-heme alkaline transition is also small. However, pH-jump kinetic studies of the His79-heme alkaline transition show that both the forward and backward rates of conformational change are increased by the Tml72 to Ala substitution. The barrier for opening the heme crevice is reduced by 0.5 kcal/mol and for closing the heme crevice by 0.3 kcal/mol. The ability of Tml72 to modulate the heme crevice dynamics may indicate a crucial role in regulating function, such as in the peroxidase activity seen in the early stages of apoptosis.
It has been previously proposed that nitric oxide (NO) is the only biologically relevant nitrogen oxide capable of activating the enzyme soluble guanylate cyclase (sGC). However, recent reports implicate HNO as another possible activator of sGC. Herein, we examine the affect of HNO donors on the activity of purified bovine lung sGC and find that, indeed, HNO is capable of activating this enzyme. Like NO, HNO activation appears to occur via interaction with the regulatory ferrous heme on sGC. Somewhat unexpectedly, HNO does not activate the ferric form of the enzyme. Finally, HNO-mediated cysteine thiol modification appears to also affect enzyme activity leading to inhibition. Thus, sGC activity can be regulated by HNO via interactions at both the regulatory heme and cysteine thiols.
Cystathionine beta-synthase (CBS) is a pyridoxal-5'-dependent enzyme that catalyzes the condensation of homocysteine and serine to form cystathionine. Human CBS is unique in that heme is also required for maximal activity, although the function of heme in this enzyme is presently unclear. The study presented herein reveals that the heme of human CBS undergoes a coordination change upon reduction at elevated temperatures. We have termed this new species "CBS424" and demonstrate that its formation is likely irreversible when pH 9 Fe(III) CBS is reduced at moderately elevated temperatures (approximately 40 degrees C and higher) or when pH 9 Fe(II) CBS is heated to similar temperatures. Spectroscopic techniques, including resonance Raman, electronic absorption, and variable temperature/variable field magnetic circular dichroism spectroscopy, provide strong evidence that CBS424 is coordinated by two neutral donor ligands. It appears likely that the native cysteine(thiolate) heme ligand is displaced by an endogenous neutral donor upon conversion to CBS424. This behavior is consistent with other six-coordinate, cysteine(thiolate)-ligated heme centers, which seek to avoid this coordination structure in the Fe(II) state. Functional assays show that CBS424 is inactive and suggest that the ligand switch is responsible for eliminating enzyme activity. When this investigation is taken together with other functional studies of CBS, it provides strong evidence that coordination of Cys52 to the heme iron is crucial for full activity in this enzyme. We hypothesize that cysteine displacement may serve as a mechanism for CBS inactivation and that second-sphere interactions of the Cys52 thiolate with surrounding residues are responsible for communicating the heme ligand displacement to the CBS active site.
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