Analysis of kombucha to teach biochemical concepts and techniques to undergraduate students.

Laboratory exercises for undergraduate biochemistry students are described in which changes in sugar content during fermentation of the trendy beverage kombucha are analyzed by three methods: thin layer chromatography, a 3,5-dinitrosalicylic acid assay, and a standard commercial blood glucose meter. Each of the three analyses can be completed in a typical laboratory session lasting two to three hours. The exercises are designed to reinforce concepts typically covered in an undergraduate biochemistry course as well as to teach a variety of laboratory techniques. The exercises have been used with positive results in an upper level biochemistry laboratory course for junior/senior students majoring in chemistry or biology. © 2019 International Union of Biochemistry and Molecular Biology, 47(4):459-467, 2019.

Use of mushroom tyrosinase to introduce michaelis-menten enzyme kinetics to biochemistry students.

An inexpensive enzyme kinetics laboratory exercise for undergraduate biochemistry students is described utilizing tyrosinase from white button mushrooms. The exercise can be completed in one or two three-hour lab sessions. The optimal amounts of enzyme, substrate (catechol), and inhibitor (kojic acid) are first determined, and then kinetic data is collected in the absence and presence of the inhibitor. A Microsoft Excel template is used to plot the data and to fit the Michaelis-Menten equation to the data to determine the kinetic parameters Vmax and Km . The exercise is designed to clarify and reinforce concepts covered in an accompanying biochemistry lecture course. It has been used with positive results in an upper-level biochemistry laboratory course for junior/senior students majoring in chemistry or biology. © 2016 by The International Union of Biochemistry and Molecular Biology, 45(3):270-276, 2017.

Structural diversity in the dandelion (Taraxacum officinale) polyphenol oxidase family results in different responses to model substrates.

Polyphenol oxidases (PPOs) are ubiquitous type-3 copper enzymes that catalyze the oxygen-dependent conversion of o-diphenols to the corresponding quinones. In most plants, PPOs are present as multiple isoenzymes that probably serve distinct functions, although the precise relationship between sequence, structure and function has not been addressed in detail. We therefore compared the characteristics and activities of recombinant dandelion PPOs to gain insight into the structure-function relationships within the plant PPO family. Phylogenetic analysis resolved the 11 isoenzymes of dandelion into two evolutionary groups. More detailed in silico and in vitro analyses of four representative PPOs covering both phylogenetic groups were performed. Molecular modeling and docking predicted differences in enzyme-substrate interactions, providing a structure-based explanation for grouping. One amino acid side chain positioned at the entrance to the active site (position HB2+1) potentially acts as a "selector" for substrate binding. In vitro activity measurements with the recombinant, purified enzymes also revealed group-specific differences in kinetic parameters when the selected PPOs were presented with five model substrates. The combination of our enzyme kinetic measurements and the in silico docking studies therefore indicate that the physiological functions of individual PPOs might be defined by their specific interactions with different natural substrates.

Site-directed mutagenesis of a tetrameric dandelion polyphenol oxidase (PPO-6) reveals the site of subunit interaction.

Polyphenol oxidases (PPOs) catalyze the oxidation of ortho-diphenols to the corresponding quinones (EC 1.10.3.1). In plants PPOs appear in gene families, and the corresponding isoenzymes are located to the thylakoid lumen of chloroplasts. Although plant PPOs are often discussed with regard to their role in defense reactions, a common physiological function has not yet been defined. We analyzed a tetrameric PPO isoenzyme (PPO-6) from dandelion (Taraxacum officinale) heterologously expressed in Escherichia coli, and found it to display cooperativity in catalysis, a phenomenon that has rarely been shown for plant PPOs previously. The identification of a surface-exposed cysteine (197) through molecular modeling followed by site-directed mutagenesis proved this amino acid residue to stabilize the tetramer via a disulfide linkage. The C197S-mutein still forms a tetrameric structure but shows impaired enzymatic efficiency and cooperativity and a reduction in stability. These findings indicate that oligomerization may be a physiological requirement for PPO-6 stability and function in vivo and raise new questions regarding distinct functions for specific PPO isoenzymes in plants.

Homology models of four Agaricus bisporus tyrosinases.

Partially purified tyrosinase from the white button mushroom Agaricus bisporus is available commercially and is a widely used experimental model for the study of tyrosinase. The structure of an H(2)L(2) tetrameric form of the mushroom enzyme was recently determined by X-ray crystallography. In this structure the two H subunits originate from the PPO3 gene, and the two L subunits are formed by a protein of unknown function with a lectin-like fold. However, the X-ray structures and oligomeric states of the mushroom PPO1, PPO2, PPO4, and PPO5 gene products remain unknown. Commercial mushroom tyrosinase powder is a mixture containing several or all of these tyrosinases, so knowledge of their structures should provide insight regarding interpretation of experimental data generated using commercial preparations of the enzyme. The PPO3 structure (H-subunit) was used as a template to generate homology models for the structures of the other four tyrosinases, and the resulting structural models were evaluated. Due to the moderate to high percentage of sequence identity (~37-76%) between PPO3 and the other four tyrosinases, the backbone conformations of the predicted structures are very similar to that of PPO3. The alpha carbons of the six copper-coordinating histidines in the active site are positioned properly in the predicted structures, but their side chains are not oriented optimally for copper binding in some cases. Thus, the models are likely to provide an accurate representation of the actual tertiary structures, but they may have limited use in studies involving docking of substrates or inhibitors in the active site. Comparison of the homology models to the structure of molluscan hemocyanin enabled a prediction of the orientation of the enzyme's C-terminal domain over the active site in the latent enzyme.

Tissue printing to visualize polyphenol oxidase and peroxidase in vegetables, fruits, and mushrooms.

A simple tissue-printing procedure to determine the tissue location of the endogenous enzymes polyphenol oxidase and peroxidase in a variety of vegetables, fruits, and mushrooms is described. In tissue printing, cell contents from the surface of a cut section of the tissue are transferred to an adsorptive surface, commonly a nitrocellulose membrane. Because of the considerable expense of nitrocellulose, our procedure utilizes artists' hot-press watercolor paper as a novel and more economical alternative. Tissue prints are then exposed to an enzyme substrate from which an insoluble, colored product is produced. The appearance of color in specific areas of the print is an indication of the presence of the enzyme in those tissue locations. The experiment is designed to enable students to learn some fundamental concepts about enzymes. It has been used in an introductory-level organic and biochemistry course for nonscience majors, but would also be appropriate for advanced high school students or could be adapted for an upper-level undergraduate biochemistry course.

Proteolytic processing of polyphenol oxidase from plants and fungi.

Polyphenol oxidase (PPO), a metalloenzyme containing a type-3 copper center, is produced by many species of plants, fungi, and bacteria. There is great variability in the subunit molecular mass reported for PPO, even from a single species. In some cases, experimental evidence (usually protein sequencing by Edman degradation) indicates that the variability in molecular mass for PPO from a given species is the result of proteolytic processing at the N and/or C-termini of the protein. In order to identify specific sequence regions where proteolysis occurs in PPO from most species, the experimentally established N and C-termini of these proteolyzed enzymes were compared to the protein sequences of other PPOs for which the N and C-termini have not been established by protein sequencing methods. In all cases the N-terminal proteolysis sites were located prior to a conserved arginine residue, and the C-terminal proteolysis sites were located following a conserved tyrosine motif. Based on the sites of proteolysis, molecular masses were calculated for the enzymes, and the calculated values were used to rationalize the varying molecular masses reported in the literature. To determine the structural implications of N and C-terminal proteolysis, the proteolysis sites were related to the two available PPO structures: Ipomoea batatas catechol oxidase and Streptomyces castaneoglobisporus tyrosinase. A structural "core" region that appears to be essential for structural stability and enzymatic activity was identified.

Introductory bioinformatics exercises utilizing hemoglobin and chymotrypsin to reinforce the protein sequence-structure-function relationship.

We describe two bioinformatics exercises intended for use in a computer laboratory setting in an upper-level undergraduate biochemistry course. To introduce students to bioinformatics, the exercises incorporate several commonly used bioinformatics tools, including BLAST, that are freely available online. The exercises build upon the students' background knowledge of hemoglobin and chymotrypsin, and foster a better understanding of how protein sequence relates to structure and function.

Comparative analysis of polyphenol oxidase from plant and fungal species.

Polyphenol oxidase from plants and fungi is a metalloenzyme containing a type-3 copper center and is homologous to oxygen-carrying hemocyanin of molluscs. Molluscan hemocyanin consists of two domains, an N-terminal domain containing the copper center and a smaller C-terminal domain, connected by an alpha-helical linker. It is presumed that the same is true of polyphenol oxidase from plants and fungi although the structure of a polyphenol oxidase containing the C-terminal domain has not been determined. We show that a number of important structural features are conserved in the N-terminal domains of polyphenol oxidases from various plants and fungi, including a tyrosine motif which can be considered a landmark indicating the beginning of the linker region connecting the N- and C-terminal domains. Our sequence alignments and secondary structure predictions indicate that the C-terminal domains of polyphenol oxidases are likely to be similar in tertiary structure to that of hemocyanin. Detailed bioinformatics analyses of the linker regions predict that this section of the polypeptide chain is intrinsically disordered (lacking fixed tertiary structure) and contains a site of proteolytic processing as well as a potential phosphorylation site.

Molecular and comparative genetics of mental retardation.

Affecting 1-3% of the population, mental retardation (MR) poses significant challenges for clinicians and scientists. Understanding the biology of MR is complicated by the extraordinary heterogeneity of genetic MR disorders. Detailed analyses of >1000 Online Mendelian Inheritance in Man (OMIM) database entries and literature searches through September 2003 revealed 282 molecularly identified MR genes. We estimate that hundreds more MR genes remain to be identified. A novel test, in which we distributed unmapped MR disorders proportionately across the autosomes, failed to eliminate the well-known X-chromosome overrepresentation of MR genes and candidate genes. This evidence argues against ascertainment bias as the main cause of the skewed distribution. On the basis of a synthesis of clinical and laboratory data, we developed a biological functions classification scheme for MR genes. Metabolic pathways, signaling pathways, and transcription are the most common functions, but numerous other aspects of neuronal and glial biology are controlled by MR genes as well. Using protein sequence and domain-organization comparisons, we found a striking conservation of MR genes and genetic pathways across the approximately 700 million years that separate Homo sapiens and Drosophila melanogaster. Eighty-seven percent have one or more fruit fly homologs and 76% have at least one candidate functional ortholog. We propose that D. melanogaster can be used in a systematic manner to study MR and possibly to develop bioassays for therapeutic drug discovery. We selected 42 Drosophila orthologs as most likely to reveal molecular and cellular mechanisms of nervous system development or plasticity relevant to MR.

Mutational analysis of the subunit interface of Vibrio harveyi bacterial luciferase.

Bacterial luciferase is a heterodimeric (alphabeta) enzyme which catalyzes a light-producing reaction in Vibrio harveyi. In addition to the alphabeta enzyme, the beta subunit can self-associate to form a stable but inactive homodimer [Sinclair, J. F., Ziegler, M. M., and Baldwin, T. O. (1994) Nat. Struct. Biol. 1, 320-326]. The studies reported here were undertaken to explore the role of the subunit interface in the conformational stability of the enzyme. To this end, we constructed four mutant heterodimers in which residues at the subunit interface were changed in an effort to alter the volume of an apparent solvent accessible channel at the interface or to alter H-bonding groups. Equilibrium unfolding data for the heterodimer have been interpreted in terms of a three-state mechanism [Clark, C. A., Sinclair, J. F., and Baldwin, T. O. (1993) J. Biol. Chem. 268, 10773-10779]. However, we found that unfolding for the wild-type and mutant luciferases is better described by a four-state model. This change in the proposed mechanism of unfolding is based on observation of residual structure in the subunits following dissociation of the heterodimeric intermediate. All of the mutants display modest reductions in activity but, surprisingly, no change in the DeltaG2H2O value for subunit dissociation and no measurable change in the equilibrium dissociation constant relative to that of the wild-type heterodimer. However, the DeltaG1H2O value for the formation of the dimeric intermediate that precedes subunit dissociation is reduced for three of the mutants, indicating that mutations at the interface can alter the stability of a region of the alpha subunit that is distant from the interface. We conclude that the interface region communicates with the distal domains of this subunit, probably through the active center region of the enzyme.