P450 enzymes have evolved into a large superfamily that displays great diversity in substrate and product specificities by fixing the natural amino acid substitutions with high frequency. Site-directed mutagenesis has been used to correlate the substitutions with the diverse specificities in various P450s. As a result, the common residues that determine the specificities of various mammalian P450s have been identified and aligned to the corresponding residues in the substrate-heme pocket of the 3-dimensional structures of bacterial P450s. The substrate-heme pocket appears to be structurally variable so that only a minor substitution (Ala -> -> Val, for example) at the critical positions is enough to define the altered specificity. Thus, the structural variability of the P450s provides the inherent versatility in acquiring a novel activity. Recent mutational studies indicate that the side chain size is the major determining factor of specificity, outweighing other factors such as polarity. Further understanding of the paradoxical characteristics observed may provide us with the underlying principles that determine P450 activities, and may lead to the ability to predict P450 activities based on the types of key amino acid residues.
Protein kinases play crucial roles in regulating virtually every cellular process and are currently attracting tremendous interest as drug targets from the pharmaceutical industry. The major challenges facing the development of the potential kinase inhibitor drugs are: selectivity, physical properties (solubility, molecular weight), and pharmacological properties (bioavailability, half life, toxicity, etc.) This review focuses on how selective protein kinase inhibitors that target the ATP and allosteric binding sites are currently being identified and optimized.
Cucumisin is a subtilisin-like serine protease (subtilase) that is found in the juice of melon fruits (Cucumis melo L.). It is synthesized as a preproprotein consisting of a signal peptide, NH 2 -terminal propeptide, and 67-kDa protease domain. We investigated the role of this propeptide (88 residues) in the cucumisin precursor. Complementary DNAs encoding the propeptides of cucumisin, two other plant subtilases (Arabidopsis ARA12 and rice RSP1), and bacterial subtilisin E were expressed in Escherichia coli independently of their mature enzymes. The cucumisin propeptide strongly inhibited cucumisin in a competitive manner with a K i value of 6.2 ؎ 0.55 nM. Interestingly, cucumisin was also strongly inhibited by ARA12 and RSP1 propeptides but not by the subtilisin E propeptide. In contrast, the propeptides of cucumisin, ARA12, and RSP1 did not inhibit subtilisin. region was thought to contribute toward the formation of a proper secondary structure necessary for cucumisin inhibition. This is the first report on the function and structural information of the propeptide of a plant serine protease.Proteases play key roles in diverse processes regulating plant growth, development, and responses to environmental stimuli. They are necessary for protein turnover, strict protein quality control, and degrading specific sets of proteins. Comparative genomics analyses could provide valuable insights into the abundance and roles of various plant protease families. For example, the Arabidopsis thaliana genome has over 550 protease sequences corresponding to almost 3% of the proteome, representing all five catalytic types: serine, cysteine, aspartic acid, metallo, and threonine (1, 2). Of these, serine proteases appear to be the largest class of plant proteases, although protease activity has been demonstrated only by a few of them.Cucumisin (EC 3.4.21.25) is an extracellular thermostable alkaline serine protease that is expressed at high levels in melon fruits (Cucumis melo L.). It comprises more than 10% of the total juice protein and is synthesized in the central parts of the fruits (3). Cucumisin is synthesized and accumulated only in melon fruits, and a cis-regulatory enhancer element in the cucumisin promoter regulates fruit-specific expression of the cucumisin gene (4). We have determined the complete nucleotide sequence of a cucumisin cDNA, the first sequenced plant serine protease, and found that cucumisin is a member of the subtilisin (EC 3.4.21.62) superfamily characterized by a catalytic triad of three amino acids: Asp, His, and Ser (5). The primary structure of cucumisin deduced from the cDNA sequence revealed that it is synthesized as a precursor consisting of four functional domains: a possible signal peptide (22 amino acid residues); NH 2 -terminal prosequence (88 residues); 54-kDa protease domain (505 residues), which is the active enzyme domain of the 67-kDa native cucumisin; and 14-kDa COOHterminal polypeptide (116 residues), which arises by limited autolysis of the 67-kDa native cucumisin (3, 5). The optimal...
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