Current Protein and Peptide Science - Volume 8, Issue 6, 2007

The first part of this paper contains an overview of protein structures, their spontaneous formation (“folding”), and the thermodynamic and kinetic aspects of this phenomenon, as revealed by in vitro experiments. It is stressed that universal features of folding are observed near the point of thermodynamic equilibrium between the native and denatured states of the protein. Here the “two-state” (“denatured state” ↔ “native state”) transition proceeds without accumulation of metastable intermediates, but includes only the unstable “transition state”. This state, which is the most unstable in the folding pathway, and its structured core (a “nucleus”) are distinguished by their essential influence on the folding/ unfolding kinetics. In the second part of the paper, a theory of protein folding rates and related phenomena is presented. First, it is shown that the protein size determines the range of a protein's folding rates in the vicinity of the point of thermodynamic equilibrium between the native and denatured states of the protein. Then, we present methods for calculating folding and unfolding rates of globular proteins from their sizes, stabilities and either 3D structures or amino acid sequences. Finally, we show that the same theory outlines the location of the protein folding nucleus (i.e., the structured part of the transition state) in reasonable agreement with experimental data.

Amyloid fibrils are highly ordered protein assemblies known to contribute to the pathology of a variety of genetic and aging-associated diseases. More recently, these fibrils have been shown to be useful as structural scaffolds in both natural biological systems and nanotechnology applications. The intense interest in amyloid fibrils has led to the investigation of well-characterized proteins, such as hen egg white lysozyme (HEWL), as model systems to examine structural and mechanistic principles that may be generally applicable to all amyloid fibrils. The purpose of this review is to critically examine the fibril-formation literature of proteins in the lysozyme family with respect to the known structure and folding properties of these proteins. The goal is to identify similarities and differences within the family, examine general misfolding / aggregation principles, and identify key areas of importance for future work on the fibril formation of these proteins.

Actinoporins are a family of 20-kDa, basic proteins isolated from sea anemones, whose activity is inhibited by preincubation with sphingomyelin. They are produced in monomeric soluble form but, when binding to the plasma membrane, they oligomerize to produce functional pores which result in cell lysis. Equinatoxin II (EqtII) from Actinia equina and Sticholysin II (StnII) from Stichodactyla helianthus are the actinoporins that have been studied in more detail. Both proteins display a β-sandwich fold composed of 10 β-strands flanked on each side by two short α-helices. Twodimensional crystallization on lipid monolayers has allowed the determination of low-resolution models of tetrameric structures distinct from the pore. However, the actual structure of the pore is not known yet. Wild-type EqtII and StnII, as well as a nice collection of natural and artificially made variants of both proteins, have been produced in Escherichia coli and purified. Their characterization has allowed the proposal of a model for the mechanism of pore formation. Four regions of the actinoporins structure seem to play an important role. First, a phosphocholine-binding site and a cluster of exposed aromatic residues, together with a basic region, would be involved in the initial interaction with the membrane, whereas the amphipathic N-terminal region would be essential for oligomerization and pore formation. Accordingly, the model states that pore formation would proceed in at least four steps: Monomer binding to the membrane interface, assembly of four monomers, and at least two distinct conformational changes driving to the final formation of the functional pore.

Protein aggregation is implicated in a plethora of neurodegenerative diseases. The proteins found to aggregate in these diseases are unrelated in their native structures and amino acid sequences, but form similar insoluble fibrils with characteristic cross-β sheet morphologies called amyloid in the aggregated state. While both the mechanism of aggregation and the structure of the aggregates are not fully understood at the molecular level, recent studies provide strong support for the idea that protein aggregation into highly stable, insoluble amyloid structures is a general property of the polypeptide chain. For proteins with a unique native state, it is known that aggregation occurs under conditions that promote native-state destabilization in vitro and in vivo. Taken together, the results of several important recent investigations suggest three broad molecular frameworks that may underlie the conversion of normally soluble peptides and proteins into insoluble amyloid fibrils: (1) edge-strand hydrogen bonding, (2) domain-swapping, and (3) self-association of amyloidogenic fragments. We argue that these underlying scenarios are not mutually exclusive and may be protein-dependent - i.e., a protein with a high content of hinge-regions may aggregate via a runaway domain-swap, whereas a protein with a high content of amyloidogenic fragments may aggregate primarily by the self-association of these fragments. These different scenarios provide frameworks to understand the molecular mechanism of polypeptide aggregation.

β-barrel membrane proteins perform a variety of functions, such as mediating non-specific, passive transport of ions and small molecules, selectively passing the molecules like maltose and sucrose and are involved in voltage dependent anion channels. Understanding the structural features of β-barrel membrane proteins and detecting them in genomic sequences are challenging tasks in structural and functional genomics. In this review, with the survey of experimentally known amino acid sequences and structures, the characteristic features of amino acid residues in β-barrel membrane proteins and novel parameters for understanding their folding and stability will be described. The development of statistical methods and machine learning techniques for discriminating β-barrel membrane proteins from other folding types of globular and membrane proteins will be explained along with their relative importance. Further, different methods including hydrophobicity profiles, rule based approach, amino acid properties, neural networks, hidden Markov models etc. for predicting membrane spanning segments of β-barrel membrane proteins will be discussed. In addition, the applications of discrimination techniques for detecting β-barrel membrane proteins in genomic sequences will be outlined. In essence, this comprehensive review would provide an overall picture about β-barrel membrane proteins starting from the construction of datasets to genome-wide applications.

D-amino acid oxidase (DAAO) is a FAD-containing flavoprotein that dehydrogenates the D-isomer of amino acids to the corresponding imino acids, coupled with the reduction of FAD. The cofactor then reoxidizes on molecular oxygen and the imino acid hydrolyzes spontaneously to the α-keto acid and ammonia. In vitro DAAO displays broad substrate specificity, acting on several neutral and basic D-amino acids: the most efficient substrates are amino acids with hydrophobic side chains. D-aspartic acid and D-glutamic acid are not substrates for DAAO. Through the years, it has been the subject of a number of structural, functional and kinetic investigations. The most recent advances are represented by site-directed mutagenesis studies and resolution of the 3D-structure of the enzymes from pig, human and yeast. The two approaches have given us a deeper understanding of the structure-function relationships and promoted a number of investigations aimed at the modulating the protein properties. By a rational and/or a directed evolution approach, DAAO variants with altered substrate specificity (e.g., active on acidic or on all D-amino acids), increased stability (e.g., stable up to 60 °C), modified interaction with the flavin cofactor, and altered oligomeric state were produced. The aim of this paper is to provide an overview of the most recent research on the engineering of DAAOs to illustrate their new intriguing properties, which also have enabled us to pursue new biotechnological applications.

The human liver cytochromes P450 (CYP P450s) are superfamily of hemoproteins responsible for catalyzing the oxidative metabolism of drugs and xenobiotics entering human body. Drug-drug/xenobiotic interactions are a major cause of therapeutic failures and adverse events. The concomitant administration of inducers with other drugs that are metabolized by CYP450 can result in their altered metabolism in the gastrointestinal tract and/ or liver. The clinical importance of such interactions includes auto induction leading to suboptimal or failed treatment. It is a major concern for the drug companies while developing new drugs. The present understanding of the mechanisms of induction of CYP P450s enzymes and their regulation has made considerable progress during last few years. However there are still gaps in our understanding on molecular aspects of CYP enzymes. Therefore, it remains the subject of intense scientific research to ascertain their in vivo function, and also better understand how the expression of CYP enzymes is regulated at the molecular level. This review analyzes and presents recent findings and concepts on xenosensors and their target genes. Emphasis is given to the molecular mechanisms and signaling pathways of CYP P450 mediated induction by xenobiotics and their potential for drug-drug interactions.