Catalytic mechanism and kinetics of malate dehydrogenase.

Malate dehydrogenase (MDH) is a ubiquitous and central enzyme in cellular metabolism, found in all kingdoms of life, where it plays vital roles in the cytoplasm and various organelles. It catalyzes the reversible NAD+-dependent reduction of L-malate to oxaloacetate. This review describes the reaction mechanism for MDH and the effects of mutations in and around the active site on catalytic activity and substrate specificity, with a particular focus on the loop that encloses the active site after the substrates have bound. While MDH exhibits selectivity for its preferred substrates, mutations can alter the specificity of MDH for each cosubstrate. The kinetic characteristics and similarities of a variety of MDH isozymes are summarized, and they illustrate that the KM values are consistent with the relative concentrations of the substrates in cells. As a result of its existence in different cellular environments, MDH properties vary, making it an attractive model enzyme for studying enzyme activity and structure under different conditions.

Identification and characterization of Schizophyllum commune type I metacaspases.

The role of programmed cell death in filamentous fungi is not well-understood, but is important due to the role of fungi in opportunistic infections. Plants, fungi and protozoa do not have caspase genes, but instead express the homologous proteins denoted metacaspases. To better understand the role of metacaspases in fungi we present an analysis of the sequences and activities of all five Type I metacaspases from Schizophyllum commune (ScMC), a mushroom-forming basiodmycete that undergoes sexual reproduction. The five Type I metacaspases of S. commune can be divided into two groups based on sequence similarity. Enzymes both with and without the N-terminal prodomain are active, but here we report on the constructs without the prodomains (Δpro). All five ScMCΔpro proteins show the highest enzymatic activity between pH 7 and 8 and require calcium for optimal activity. Optimal Ca2+ concentrations for ScMC1Δpro and ScMC2Δpro are 50 mM, while ScMC3, ScMC4Δpro and ScMC5Δpro activity is optimal around 5 mM calcium. All five S. commune metacaspases have similar substrate specificity. They are most active with Arg in the P1 position and inactive with Asp in the P1 position.

The chemical biology of Cu(II) complexes with imidazole or thiazole containing ligands: Synthesis, crystal structures and comparative biological activity.

The synthesis and characterization of two copper(II) complexes containing 2-(2-pyridyl)benzimidazole (PyBIm) are reported with the biological activity of these two complexes and a third Cu(II) complex containing 2-(2-pyridyl)benzothiazole (PyBTh). Complex 1, [Cu(PyBIm)(NO3)(H2O)](NO3), is a four coordinate, distorted square planar species with one ligand (N,N), nitrate and water bound to Cu(II). The [Cu(PyBIm)3](BF4)2 complex (2) has distorted octahedral geometry with a 3:1 Py(BIm) ligand to metal ratio. The distorted trigonal bi-pyramidal geometry of compound 3, [Cu(PyBTh)2(H2O)](BF4)2, is comprised of two PyBTh ligands and one water. Biological activity of 1-3 has been assessed by analyzing DNA interaction, nuclease ability, cytotoxic activity and antibacterial properties. Complex 3 exhibits potent concentration dependent SC-DNA cleavage forming single- and double-nicked DNA in contrast to the weak activity of complexes 1 and 2. Mechanistic studies indicate that all complexes utilize an oxidative mechanism however 1 and 2 employ O2(-) as the principal reactive oxygen species while the highly active 3 utilizes (1)O2. The interaction between 1-3 and DNA was investigated using fluorescence emission spectroscopy and revealed all complexes strongly intercalate DNA with Kapp values of 2.65 × 10(6), 1.85 × 10(6) and 2.72 × 10(6)M(-1), respectively. Cytotoxic effects of 1-3 were examined using HeLa and K562 cells and show cell death in the micromolar range with the activity of 1 ≈ 2 and were slightly higher than 3. Similar reactivity was observed in the antibacterial studies with E. coli and S. aureus. A detailed comparative analysis of the three complexes is presented.

Synthesis, characterization, crystal structures and biological activity of set of Cu(II) benzothiazole complexes: artificial nucleases with cytotoxic activities.

A series of Cu(II) complexes with ligand frames based on quinoline derivatives appended with a benzothiazole substituent has been isolated. The complexes, Cu(Q(oBt))(NO3)2(H2O)∙CH3OH (1∙CH3OH), Cu(8OHQ(oBt))Cl2∙CH3OH (2∙CH3OH), Cu(8OQ(oBt))Cl(CH3OH)∙CH3OH (3∙CH3OH) and [Cu(8OH1/2Q(oBt))(CH3OH)(NO3)]2(NO3) (4) have been characterized by single crystal X-ray diffraction, IR and UV-visible spectroscopies, and elemental analysis. The ligand frame within the set of complexes differs in the substituent on the quinoline ring: complex 1 remains unsubstituted at this position while complexes 2-4 have a substituted OH group. In complex 2, the bound phenol remains protonated while in 3 it is a phenolato group. Complex 4 contains two complexes within the unit cell and one NO3(-) giving rise to an overall 'half-protonation'. The interaction between complexes 1-3 with CT-DNA was investigated using fluorescence emission spectroscopy and revealed 2 and 3 strongly intercalate DNA with Kapp values of 1.47×10(7)M(-1) and 3.09×10(7)M(-1), respectively. The ability of complexes 1-3 to cleave SC-DNA was monitored using gel electrophoresis. Each complex exhibits potent, concentration dependent nuclease activity forming single and double-nicked DNA as low as 10µM. The nuclease activity of complexes 1-3 is primarily dependent on (1)O2 species while ·OH radicals play a secondary role in the cleavage by complexes 2 and 3. The cytotoxic effects of 1-3 were examined using HeLa cells and show cell death in the micromolar range. The distribution of cell cycle stages remains unchanged when complexes are present indicating DNA damage may be occurring throughout the cell cycle.

Foundational concepts and underlying theories for majors in "biochemistry and molecular biology".

Over the past two years, through an NSF RCN UBE grant, the ASBMB has held regional workshops for faculty members and science educators from around the country that focused on identifying: 1) core principles of biochemistry and molecular biology, 2) essential concepts and underlying theories from physics, chemistry, and mathematics, and 3) foundational skills that undergraduate majors in biochemistry and molecular biology must understand to complete their major coursework. Using information gained from these workshops, as well as from the ASBMB accreditation working group and the NSF Vision and Change report, the Core Concepts working group has developed a consensus list of learning outcomes and objectives based on five foundational concepts (evolution, matter and energy transformation, homeostasis, information flow, and macromolecular structure and function) that represent the expected conceptual knowledge base for undergraduate degrees in biochemistry and molecular biology. This consensus will aid biochemistry and molecular biology educators in the development of assessment tools for the new ASBMB recommended curriculum.

Ontogenetic changes in citrate synthase and lactate dehydrogenase activity in the jumping muscle of the American locust (Schistocerca americana).

Intraspecific studies have repeatedly shown that muscle-specific oxidative enzyme activities scale negatively with body mass while muscle-specific glycolytic enzyme activities scale positively. However, most of these studies have not included juveniles. In this study, we examined how citrate synthase (CS, EC 2.3.3.1) and lactate dehydrogenase (LDH; EC 1.1.1.27) activity in the jumping muscle of Schistocerca americana grasshoppers varied with ontogeny across a 40-fold increase in body size. In contrast to the pattern observed when adult conspecifics are compared, we show that jumping muscle CS activity increased more than 2-fold from 2nd instars to adults, while jumping muscle LDH activity increased more than 5-fold. The increased LDH activity in older grasshoppers supports previous data that older grasshoppers have a reduced jumping endurance. The increased CS activity with age may help older grasshoppers efficiently produce aerobic ATP to bend cuticular springs for energy storage before a jump or alternatively recover from anaerobic metabolism after jumping. Metabolic changes in S. americana jumping muscle are similar to other developing taxa and highlight the importance of including juveniles within intraspecific studies. When compared to adults, juvenile locomotion may have increased selection pressure because of both greater energetic demands during growth and higher predation rates.