This paper presents the effect of additives on the mechanism and selectivity of the SmI2-mediated
coupling of alkyl halides and ketones. The reaction of 1-iodobutane and 2-octanone was carried out with SmI2
in the absence of cosolvent and in the presence of HMPA, LiBr, and LiCl. The experiments using cosolvent
free SmI2 and SmI2−HMPA reductants gave the Barbier product, 5-methyl-5-undecanol predominantly. The
same procedure carried out with LiBr as an additive produced the pinacol product, 7,8-dimethyl-7,8-tetradecanediol, exclusively. A careful product analysis of the SmI2-mediated coupling of 1-iodododecane and
2-octanone in the presence of LiBr, LiCl, and HMPA was also performed. The combination of SmI2 and LiBr
again produced the pinacol coupling product exclusively and left the 1-iodododecane unreduced. In contrast,
the SmI2−HMPA combination gave only the Barbier product. Analysis of the Sm(II) reductants employing
cyclic voltammetry and UV−vis spectroscopy coupled with reaction protocol changes and mechanistic studies
led to the conclusion that the SmI2-mediated coupling of alkyl halides and carbonyls in the presence of HMPA
gives the Barbier product through an outer-sphere electron-transfer process, while the reaction utilizing SmI2
with LiBr or LiCl gives the pinacol product through an inner-sphere reductive coupling of ketones. The results
presented herein show that it is possible to alter the reactivity and selectivity of Sm(II) reagents through the
choice of additives or cosolvents, primarily by changing the steric bulk around the reductant.
The role of HMPA as a ligand for SmI2 and the stoichiometry and energetics of formation for the
SmI2−HMPA complex in THF were investigated employing UV−vis spectroscopy, isothermal
titration calorimetry (ITC), and vapor pressure osmometry (VPO). The aggregation number for
SmI2 in THF was found to be 0.98 ± 0.09 over the entire concentration range studied (6.71−84.0
mM), indicating that SmI2 is monomeric. The UV−vis data suggest that four HMPA ligands
coordinate to SmI2, and this was supported by ITC experiments. The combined results are consistent
with [SmI2(HMPA)4] being the reductant responsible for the unique reactivity exhibited by SmI2−HMPA cosolvent combinations.
DmpK from Pseudomonas sp. strain CF600 represents a group of proteins required by phenol-degrading bacteria that utilize a multicomponent iron-containing phenol hydroxylase. DmpK has been overexpressed in Escherichia coli and purified to homogeneity; it lacks redox cofactors and was found to strongly inhibit phenol hydroxylase in vitro. Chemical cross-linking experiments established that DmpK binds to the two largest subunits of the oxygenase component of the hydroxylase; this may interfere with binding of the hydroxylase activator protein, DmpM, causing inhibition. Since expression of DmpK normally appears to be much lower than that of the components of the oxygenase, inhibition may not occur in vivo. Hence, the interaction between DmpK and the oxygenase manifested in the inhibition and crosslinking results prompted construction of E. coli strains in which the oxygenase component was expressed in the presence and absence of a low molar ratio of DmpK. Active oxygenase was detected only when expressed in the presence of DmpK. Furthermore, inactive oxygenase could be activated in vitro by adding ferrous iron, in a process that was dependent on the presence of DmpK. These results indicate that DmpK plays a role in assembly of the active form of the oxygenase component of phenol hydroxylase.
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