Novel cofactor derivatives and cofactor-based models

In 1997 and the first half of 1998, numerous publications appeared reporting studies of cofactors and their analogues in classical model systems and in enzyme-catalyzed reactions directed at understanding the enzymatic reactions of their natural cofactors. Model systems based on flavins have provided new insights into enzymatic modulation of the flavin reduction potential, and enzymatic reactions of coenzyme A analogues and derivatives have been employed in several studies of coenzyme A utilizing enzymes. Coenzyme B₁₂ analogues have been utilized as alternate cofactors for B₁₂-utilizing enzymes, while pyrroloquinoline quinone esters and analogues have been employed in model studies of the reactions of quinoprotein-catalyzed reactions.     

Novel metal sites in protein structures

Recently, the three-dimensional structures of several novel metalloenzymes have been solved. Of special interest are those containing uncommon and/or not well characterized metals such as molybdenum, tungsten, nickel, vanadium and cobalt. Modulated by the protein environment, the specific properties of these metals and of special metal-binding cofactors such as siroheme and topa quinone are used to catalyze a vast array of fascinating reactions.     

Biosynthetic systems for nonribosomal peptide antibiotic assembly

Modular peptide synthetases, which act as the protein templates for the synthesis of a large number of peptide antibiotics and siderophores, hold great potential for the development of novel compounds. Recently, significant progress has been made towards understanding their molecular architecture and substrate specificity. The first crystal structure of a peptide synthetase has been solved, and the enzymes responsible for post-translational modification of peptide synthetases have recently been discovered. These will allow addressing important yet poorly understood mechanistic aspects.     

Chemical approaches toward understanding base excision DNA repair

Despite the importance of DNA repair in protecting the genome, the molecular basis for damage recognition and repair remains poorly understood. In the base excision repair pathway (BER), DNA glycosylases recognize and excise damaged bases from DNA. This review focuses on the recent development of chemical approaches that have been applied to the study of BER enzymes. Several distinctive classes of noncleavable substrate analogs that form stable complexes with DNA glycosylases have recently been designed and synthesized. These analogs have been used for biochemical and structural analyses of protein—DNA complexes involving DNA glycosylases, and for the isolation of a novel DNA glycosylase. An approach to trap covalently a DNA glycosylase-intermediate complex has also been used to elucidate the mechanism of DNA glycosylases.     

Enzyme models: design and selection

There are two approaches to the discovery of enzyme mimics, that is identifying molecules that are able to bind substrate(s) and then catalyze reactions. The first approach, often inspired by enzymes themselves, utilises chemical knowledge and experience to design the catalyst. The other approach is to create a library and select the best host of a transition state analogue of the required reaction.     

Structure, evolution and action of vitamin B6-dependent enzymes

The number of known three-dimensional structures of vitamin B₆-dependent enzymes has doubled in the past two years. A fourth type of fold for B₆-dependent enzymes, involving a TIM-barrel domain, has been discovered. Alanine racemase is the first known representative of this new fold. Significant progress has been made in understanding the allosteric effects in the tryptophan synthase reaction.     

Progress towards synthetic enzymes for phosphoester hydrolysis

Synthesis of artificial enzymes for catalyzing phosphoester hydrolysis has been attracting interest for a long time. The remarkable discovery that lanthanide ions catalyze the hydrolysis of DNA and RNA spurred the trend. Currently, progress is being made, mainly in the preparation of homogeneous catalysts, the promotion of catalytic activity by using acid/base cooperation within catalysts, the detailed understanding of the reaction mechanisms involved, and the design of artificial enzymes expressing high specificity and catalytic turn-over.     

Intracellular detection assays for high-throughput screening

New optical assay methods promise to accelerate the use of living cells in screens for drug discovery. Most of these methods employ either fluorescent or luminescent read-outs and allow cell-based assays for most targets, including receptors, ion channels and intracellular enzymes. Furthermore, genetically encoded probes offer the possibility of custom-engineered biosensors for intracellular biochemistry, specifically localized targets, and protein—protein interactions.     

Regulatory roles of cyclin dependent kinase phosphorylation in cell cycle control

Cyclins and cyclin-dependent kinases (Cdks) are universal regulators of cell cycle progression in eukaryotic cells. Cdk activity is controlled by phosphorylation at three conserved sites, and many of the enzymes that act on these sites have now been identified. Although the biochemistry of CdK phosphorylation is relatively well understood, the regulatory roles of such phosphorylation are, in many cases, obscure. Recent studies have uncovered new and unexpected potential roles, and prompted re-examination of previously assumed roles, of Cdk phosphorylation.     

The metaphase-to-anaphase transition: avoiding a mid-life crisis

The metaphase-to-anaphase transition is a highly regulated process, which is governed by the activity of the anaphase-promoting complex (APC). The APC promotes the degradation of several proteins, including mitotic cyclins and newly identified anaphase inhibitors. Several discoveries made this year shed invaluable light on the regulation of APC activation and its substrate specificity.     

Aminoacyl-tRNA synthetases

Crystallographic studies of a number of aminoacyl-tRNA synthetases and their complexes with ATP, amino acid and cognate tRNA are leading to an increasingly detailed picture of how these sophisticated enzymes function. Within the two distinct structural classes of ten synthetases, many common features are apparent, although evolution has led to many interesting idiosyncrasies in certain enzymes. Recent advances, specially concerning class II enzymes, have increased out knowledge of both the role of electrophiles in the mechanism of amino acid activation and cross-subunit tRNA recognition and help solve the evolutionary puzzles that have emerged from the extension of the aminoacyl-tRNA synthetase database to include Archae     

Chain elongation in the isoprenoid biosynthetic pathway

Isoprenyl diphosphate synthases catalyze addition of allylic diphosphate primers to the isoprene unit in isopentenyl diphosphate to produce polyisoprenoid diphosphates with well defined chain lengths. Phylogenetic correlations suggest that the synthases which catalyze formation of isoprenoid diphosphates with (E) double bonds have evolved from a common ancestor. X-ray crystallographic studies of farnesyl diphosphate synthase in conjunction with site-directed mutagenesis have provided important new information about the residues involved in binding and catalysis and the source of chain length selectivity for the enzymes that catalyze chain elongation.     

Antifreeze proteins

Antifreeze proteins comprise a structurally diverse class of proteins that inhibit the growth of ice. Recently, new AFP types have been discovered; more active AFPs have been isolated; antecedents have been recognized supporting the notion of recent, multiple origins; and detailed structures have emerged leading to models for their adsorption to ice     

Theozymes and compuzymes: theoretical models for biological catalysis

A theozyme is a theoretical enzyme constructed by computing the optimal geometry for transition-state stabilization by functional groups. It is created in order to permit quantitative assessment of catalytic function. Theozymes have been used to elucidate the role of transition-state stabilization in the mechanisms underlying enzyme- and antibody-catalyzed hydroxyepoxide cyclizations, eliminations and decarboxylations, peptide and ester hydrolyses, and pericyclic and radical reactions. The enzymes studied include orotodine monophosphate decarboxylase, HIV protease and ribonucleotide reductase.     

Reproductive isolation in Drosophila: how close are we to untangling the genetics of speciation?

Our understanding of the genetic basis of reproductive isolation in Drosophila has progressed rapidly over the past decade. Details of the genetic structure of hybrid sterility have been revealed and a general consensus has been reached concerning the genetic bases of Haldane's rule. Genetic analyses now reach beyond hybrid sterility and inviability, allowing us to make important comparisons across different traits involved in reproductive isolation. Expansion of genetic studies to include rescue of hybrid incompatibilities has opened the door for more detailed molecular and developmental analyses of reproductive isolation than has ever before been possible.     

Mutation for survival

Adaptive mutations appear in response to selection. In the best-studied system, the two most controversial issues were resolved this year. The mutations are neither Lamarckian nor a peculiarity of bacterial sex, as had been suggested. They occur genome-wide in a hypermutable subpopulation of stressed cells. Genomic ‘hot’ and ‘cold’ regions may explain previous failures to detect similar mutations in other systems and at other sites. Stationary phase specific limitation of mismatch repair has also been discovered.     

Glutamine PRPP amidotransferase: snapshots of an enzyme in action

Recent studies of glutamine PRPP amidotransferase have provided a new understanding of the function and mechanism of this rather complicated enzyme that may be a paradigm for other complex enzymes. New insights have been gained into the mechanisms of catalysis in the active sites of the two half-reactions, catalytic coupling, allosteric control by feedback inhibitors and the channeling of reaction and metabolic intermediates.     

Minimal model systems for β-sheet secondary structure in proteins

Use of model systems to explore the forces that control β sheet formation was stymied for many years by the perception that small increments of β sheet necessarily aggregate. Recently, however, a number of short peptides (9–16 residues in length) that fold into two-stranded antiparallel β sheets (‘β hairpins’) have been reported; several short peptides (20–24 residues in length) that fold into three-stranded antiparallel β sheets have also been described. These model systems are beginning to provide fundamental insights into the origins of β sheet conformational stability.