A novel AKT3 mutation in melanoma tumours and cell lines.

Recently, a rare activating mutation of AKT1 (E17K) has been reported in breast, ovarian, and colorectal cancers. However, analogous activating mutations in AKT2 or AKT3 have not been identified in any cancer lineage. To determine the prevalence of AKT E17K mutations in melanoma, the most aggressive form of skin cancer, we analysed 137 human melanoma specimens and 65 human melanoma cell lines for the previously described activating mutation of AKT1, and for analogous mutations in AKT2 and AKT3. We identified a single AKT1 E17K mutation. Remarkably, a previously unidentified AKT3 E17K mutation was detected in two melanomas (from one patient) as well as two cell lines. The AKT3 E17K mutation results in activation of AKT when expressed in human melanoma cells. This represents the first report of AKT mutations in melanoma, and the initial identification of an AKT3 mutation in any human cancer lineage. We have also identified the first known human cell lines with naturally occurring AKT E17K mutations.

High-level misincorporation of lysine for arginine at AGA codons in a fusion protein expressed in Escherichia coli.

The expression of eukaryotic genes in Escherichia coli is one of the most frequently used tools of modern science. The arginine codon AGA is a common codon in eukaryotic genes but is particularly rare in E. coli. We report here 36 to 42% misincorporation of lysine at three AGA codons in a well-expressed protein. This misincorporation yields a protein whose electrospray mass spectrum (ESMS) shows peaks at the expected mass (M), M-28, M-56 and M-84 with intensities representing 34.5(+/-0.7), 37.5(+/-1.1), 21.2(+/-1.7) and 6.6(+/-0.5) % of the total intensity, respectively. Replacement of either all three AGA codons or the two closest to the 3' end of the gene by the more common CGC arginine codon gave a protein with a single ESMS peak. Misincorporation could also be eliminated by the co-expression of the tRNA(UCL)Arg gene, argU. These studies demonstrate that misincorporation of amino acids at rare codons of recombinant proteins can be far higher than previously thought.

Functional consequences of engineering the hydrophobic pocket of carbonic anhydrase II.

Twelve amino acid substitutions of varying size and hydrophobicity were constructed at Val 143 in human carbonic anhydrase II (including Gly, Ser, Cys, Asn, Asp, Leu, Ile, His, Phe and Tyr) to examine the catalytic roles of the hydrophobic pocket in the active site of this enzyme. The CO2 hydrase and p-nitrophenyl acetate (PNPA) esterase activities, the pKa of the zinc-water ligand, the inhibition constant for cyanate (KOCN), and the binding constants for sulfonamide inhibitors were measured for various mutants and correlated with the size and hydrophobicity of the substituted amino acid. The kcat/KM for PNPA hydrolysis and KOCN are linearly dependent on the hydrophobicity of the amino acid at position 143. All of the activities of CAII are decreased by more than a factor of 10(3) when large amino acids (Phe and Tyr) are substituted for Val 143, but the CO2 hydrase activity is the most sensitive to the size and structure of the substituted amino acid. Addition of a single methyl group (V143I) decreases the activity 8-fold, while substitution of valine by tyrosine essentially destroys the enzyme function (kcat/KM for CO2 hydration is decreased by more than 10(5)-fold). KOCN does not increase until Phe is substituted for Val 143, suggesting that the cyanate and CO2 binding sites are not identical. The functional data in conjunction with X-ray crystallographic studies of four of the mutants [Alexander et al., 1991 (following paper in this issue)] allow interpretation of the mutants at a molecular level and mapping of the region of the active site important for CO2 association. The hydrophobic pocket, including residues Val 121 and Val 143, is important for CO2 and PNPA association; if the pocket is blocked, substrates cannot approach the zinc-hydroxide with the correct orientation to react. The interaction between Val 143 and CO2 is relatively weak (less than or equal to 0.5 kcal/mol) and nonspecific; the association site does not tightly hold CO2 in one fixed orientation for reaction with the zinc-hydroxide. This mechanism of catalysis may reflect a decreased requirement for specific orientation by CO2 since it is a symmetrical molecule.

Altering the mouth of a hydrophobic pocket. Structure and kinetics of human carbonic anhydrase II mutants at residue Val-121.

Eleven amino acid substitutions at Val-121 of human carbonic anhydrase II including Gly, Ala, Ser, Leu, Ile, Lys, and Arg, were constructed by site-directed mutagenesis. This residue is at the mouth of the hydrophobic pocket in the enzyme active site. The CO2 hydrase activity and the p-nitrophenyl esterase activity of these CAII variants correlate with the hydrophobicity of the residue, suggesting that the hydrophobic character of this residue is important for catalysis. The effects of these mutations on the steady-state kinetics for CO2 hydration occur mainly in kcat/Km and Km, consistent with involvement of this residue in CO2 association. The Val-121----Ala mutant, which exhibits about one-third normal CO2 hydrase activity, has been studied by x-ray crystallographic methods. No significant changes in the mutant enzyme conformation are evident relative to the wild-type enzyme. Since Val-121 is at the mouth of the hydrophobic pocket, its substitution by the methyl side chain of alanine makes the pocket mouth significantly wider than that of the wild-type enzyme. Hence, although a moderately wide (and deep) pocket is important for substrate association, a wider mouth to this pocket does not seriously compromise the catalytic approach of CO2 toward nucleophilic zinc-bound hydroxide.

Uniform 13C isotope labeling of proteins with sodium acetate for NMR studies: application to human carbonic anhydrase II.

Uniform double labeling of proteins for NMR studies can be prohibitively expensive, even with an efficient expression and purification scheme, due largely to the high cost of [13C6, 99%]glucose. We demonstrate here that uniformly (greater than 95%) 13C and 15N double-labeled proteins can be prepared for NMR structure/function studies by growing cells in defined media containing sodium [1,2-13C2, 99%]acetate as the sole carbon source and [15N, 99%]ammonium chloride as the sole nitrogen source. In addition, we demonstrate that this labeling scheme can be extended to include uniform carbon isotope labeling to any desired level (below 50%) by utilizing media containing equal amounts of sodium [1-13C, 99%]acetate and sodium [2-13C, 99%]acetate in conjunction with unlabeled sodium acetate. This technique is less labor intensive and more straightforward than labeling using isotope-enriched algal hydrolysates. These labeling schemes have been used to successfully prepare NMR quantities of isotopically enriched human carbonic anhydrase II. The activity and the 1H NMR spectra of the protein labeled by this technique are the same as those obtained from the protein produced from media containing labeled glucose; however, the cost of the sodium [1,2-13C2, 99%]acetate growth media is considerably less than the cost of the [13C6, 99%]glucose growth media. We report here the first published 13C and 15N NMR spectra of human carbonic anhydrase II as an important step leading to the assignment of this 29-kDa zinc metalloenzyme.

The energy landscape of a fast-folding protein mapped by Ala-->Gly substitutions.

A moderately stable protein with typical folding kinetics unfolds and refolds many times during its cellular lifetime. In monomeric lambda repressor this process is extremely rapid, with an average folded state lifetime of only 30 milliseconds. A thermostable variant of this protein (G46A/G48A) unfolds with the wild-type rate, but it folds in approximately 20 microseconds making it the fastest-folding protein yet observed. The effects of alanine to glycine substitutions on the folding and unfolding rate constants of the G46A/G48A variant, measured by dynamic NMR spectroscopy, indicate that the transition state is an ensemble comprised of a disperse range of conformations. This structural diversity in the transition state is consistent with the idea that folding chains are directed towards the native state by a smooth funnel-like conformational energy landscape. The kinetic data for the folding of monomeric lambda repressor can be understood by merging the new energy landscape view of folding with traditional models. This hybrid model incorporates the conformational diversity of denatured and transition state ensembles, a transition state activation energy, and the importance of intrinsic helical stabilities.