The structure of monomeric serine carboxypeptidase from Saccharomyces cerevisiae (CPD-Y), deglycosylated by an efficient new procedure, has been determined by multiple isomorphous replacement and crystallographic refinement. The model contains 3333 non-hydrogen atoms, all 421 amino acids, 3 of 4 carbohydrate residues, 5 disulfide bridges, and 38 water molecules. The standard crystallographic R-factor is 0.162 for 10,909 reflections observed between 20.0- and 2.8-A resolution. The model has rms deviations from ideality of 0.016 A for bond lengths and 2.7 degrees for bond angles and from restrained thermal parameters of 7.9 A2. CPD-Y, which exhibits a preference for hydrophobic peptides, is distantly related to dimeric wheat serine carboxypeptidase II (CPD-WII), which has a preference for basic peptides. Comparison of the two structures suggests that substitution of hydrophobic residues in CPD-Y for negatively charged residues in CPD-WII in the binding site is largely responsible for this difference. Catalytic residues are in essentially identical configurations in the two molecules, including strained main-chain conformational angles for three active site residues (Ser 146, Gly 52, and Gly 53) and an unusual hydrogen bond between the carboxyl groups of Glu 145 and Glu 65. The binding of an inhibitor, benzylsuccinic acid, suggests that the C-terminal carboxylate binding site for peptide substrates is Asn 51, Gly 52, Glu 145, and His 397 and that the "oxyanion hole" consists of the amides of Gly 53 and Tyr 147. A surprising result of the study is that the domains consisting of residues 180-317, which form a largely alpha-helical insertion into the highly conserved cores surrounding the active site, are quite different structurally in the two molecules. It is suggested that these domains have evolved much more rapidly than other parts of the molecule and are involved in substrate recognition.
Crystal structures of the tetrameric yellow-fluorescent protein zFP538 from the button polyp Zoanthus sp. and a green-emitting mutant (K66M) are presented. The atomic models have been refined at 2.7 and 2.5 Å resolution, with final crystallographic R factors of 0.206 (Rfree = 0.255) and 0.190 (Rfree = 0.295), respectively, and have excellent stereochemistry. The fold of the protomer is very similar to that of green (GFP) and red (DsRed) fluorescent proteins; however, evidence from crystallography and mass spectrometry suggests that zFP538 contains a three-ring chromophore derived from that of GFP. The yellow-emitting species (λemmax = 538 nm) is proposed to result from a transimination reaction in which a transiently appearing DsRed-like acylimine is attacked by the terminal amino group of lysine 66 to form a new six-membered ring, cleaving the polypeptide backbone at the 65−66 position. This extends the chromophore conjugation by an additional double bond compared to GFP, lowering the absorption and emission frequencies. Substitution of lysine 66 with aspartate or glutamate partially converts zFP538 into a red-fluorescent protein, providing additional support for an acylimine intermediate. The diverse and unexpected roles of the side chain at position 66 give new insight into the chemistry of chromophore maturation in the extended family of GFP-like proteins.
A method is proposed that permits the structural similarity between any pair of proteins to be analyzed in a completely general manner. In the proposed procedure, all possible structural segments of a given length from one protein are compared with all possible segments from the other protein. This set of comparisons reveals any structural similarities between the two proteins being compared, and also provides a basis for estimating the probability that a particular degree of structural homology could have occurred by chance. Application of the method to the comparison of T4 bacteriophage lysozyme and carp calcium-binding protein suggests that the previously reported structural similarity between parts of these two proteins [Tufty, R. M.& Kretsinger, R. H. (1975) Science 187, 167-169] is no better than would be expected by chance. On the other hand, the structural correspondence between phage lysozyme and hen egg-white lysozyme [Rossman, M.G. & Argos, P. (1976) J. Mol. Biol. 105, 75-96] does appear to be significant.
The three dimensional structure of the lysozyme from bacteriophage T4 has been determined from a 2.5 Å resolution electron density map. About 60% of the molecule is in a helical conformation and there is one region consisting of antiparallel β-structure. The polypeptide backbone folds into two distinct lobes linked in part by a long helix. In the region between the two lobes, there is a cleft which deepens into a hole or cavity, about 6-8 Å in diameter, extending from one side of the molecule to the other. This opening is closed off by side chains which extend to within 3-5 Å of each other. A number of mutant lysozymes in which residues in the vicinity of the opening are modified have markedly reduced catalytic activity, suggesting that this region of the molecule may be catalytically important. The three dimensional structure of T4 phage lysozyme is quite different from that of hen egg-white lysozyme although it is not clear at this time whether or not the mechanisms of catalysis of the respective enzymes are related.
Arabidopsis (Arabidopsis thaliana) was transformed with a redox-sensing green fluorescent protein (reduction-oxidation-sensitive green fluorescent protein [roGFP]), with expression targeted to either the cytoplasm or to the mitochondria. Both the mitochondrial and cytosolic forms are oxidation-reduction sensitive, as indicated by a change in the ratio of 510 nm light (green light) emitted following alternating illumination with 410 and 474 nm light. The 410/474 fluorescence ratio is related to the redox potential (in millivolts) of the organelle, cell, or tissue. Both forms of roGFP can be reduced with dithiothreitol and oxidized with hydrogen peroxide. The average resting redox potentials for roots are -318 mV for the cytoplasm and -362 mV for the mitochondria. The elongation zone of the Arabidopsis root has a more oxidized redox status than either the root cap or meristem. Mitochondria are much better than the cytoplasm, as a whole, at buffering changes in redox. The data show that roGFP is redox sensitive in plant cells and that this sensor makes it possible to monitor, in real time, dynamic changes in redox in vivo.
