Current Protein and Peptide Science - Volume 18, Issue 5, 2017

Clostridium botulinum group III strains are able to produce cytotoxins, C2 toxin and C3 exotoxin, along with botulinum neurotoxin types C and D. C2 toxin and C3 exotoxin produced by this organism are the most important members of bacterial ADP-ribosyltransferase superfamily. Both toxins have distinct pathophysiological functions in the avian and mammalian hosts. The members of this superfamily transfer an ADP-ribose moiety of NAD+ to specific eukaryotic target proteins. The present review describes the structure, function and evolution aspects of these toxins with a special emphasis to the development of veterinary vaccines. C2 toxin is a binary toxin that consists of a catalytic subunit (C2I) and a translocation subunit (C2II). C2I component is structurally and functionally similar to the VIP2 and iota A toxin whereas C2II component shows a significant homology with the protective antigen from anthrax toxin and iota B. Unlike C2 toxin, C3 toxin is devoid of translocation/binding subunit. Extensive studies on their sequence-structure-function link spawn additional efforts to understand the catalytic mechanisms and target recognition. Structural and functional relationships with them are often determined by using evolutionary constraints as valuable biological measures. Enzyme-deficient mutants derived from these toxins have been used as drug/protein delivery systems in eukaryotic cells. Thus, current knowledge on their molecular diversity is a well-known perspective to design immunotoxin or subunit vaccine for C. botulinum infection.

Cyclic depsipeptides (CDPs) are a family of cyclic peptide-related compounds, of which the ring is mainly composed of amino- and hydroxy acid residues joined by amide and ester bonds (at least one), leading to a wide diversity of fascinating chemical structures. They differ in both their ring structure and their side chains, especially by the nature of the unusual and non-amino acid building blocks. To date, however, there is no overall uniform chemical classification system available for CDPs and naming of the diverse family members is done rather arbitrarily. Therefore, a broad evaluation of different CDP structures is done, i.e., 1348 naturally occurring CDPs were included, and a straightforward chemical classification system using apparent chemical characteristics is proposed in order to organize the currently scattered CDP data. The overall validity of the classification approach is verified and the compounds categorized in the same groups are considered to be structurally related. This evaluation also revealed that traditionally formed CDP subfamilies, like the dolastatins, might be misleading from a chemical point of view given the structural differences in this subfamily. This up-to-date CDP overview enables peptide and natural product scientists to study the wide diversity in CDP structures, their chemical interrelationships and identification of existing and newly found CDPs. Together with the available information on the species producing these CDPs and their reported biological activities, this paper provides a useful tool to gain new insights into this diverse group of peptides.

Prostate cancer is one of the major threats to the man’s health. There are several mechanisms of the prostate cancer development characterized by the involvement of various androgen-related and androgen-unrelated factors in prostate cancer pathogenesis and in the metastatic carcinogenesis of prostate. In all these processes, proteins play various important roles, and the KEGG database has information on 88 human proteins experimentally shown to be involved in prostate cancer. It is known that many proteins associated with different human maladies are intrinsically disordered (i.e., they do not have stable secondary and/or tertiary structure in their unbound states). The goal of this review is to consider several highly disordered proteins known to be associated with the prostate cancer pathogenesis in order to better understand the roles of disordered proteins in this disease. We also hope that consideration of the pathology-related proteins from the perspective of intrinsic disorder can potentially lead to future experimental studies of these proteins to find novel pathways associated with prostate cancer.

Sex differentiation is a complex process where sexually indifferent embryo progressively acquires male or female characteristics via tightly controlled, perfectly timed, and sophisticatedly intertwined chain of events. This process is controlled and regulated by a set of specific proteins, with one of the first steps in sex differentiation being the activation of the Y-chromosomal Sry gene (sexdetermining region Y) in males that acts as a switch from undifferentiated gonad somatic cells to testis development. There are several key players in this process, which constitute the Sry transcriptional network, and collective action of which governs testis determination. Although it is accepted now that many proteins engaged in signal transduction as well as regulation and control of various biological processes are intrinsically disordered (i.e., do not have unique structure and remain unstructured, or incompletely structured, under physiological conditions), the roles and profusion of intrinsic disorder in proteins involved in the male sex determination have not been accessed as of yet. The goal of this study is to cover this gap by analyzing some key players of the Sry transcriptional network. To this end, we employed a broad set of computational tools for intrinsic disorder analysis and conducted intensive literature search in order to gain information on the structural peculiarities of the Sry networkrelated proteins, their intrinsic disorder predispositions, and the roles of intrinsic disorder in their functions.

Cytochrome P450 17α-hydroxylase, 17,20-lyase (P450c17) is a key enzyme in the synthesis of cortisol in the zona fascicula of the adrenal cortex, and the synthesis of androgen precursors in the adrenal zona reticularis and the gonads. Each of these reactions require electrons transferred by the electron donor cytochrome P450 oxidoreductase. The 17α-hydroxylation of its substrate occurs in all cells where P450c17 is expressed. Remarkably, a second, subsequent reaction, namely the 17,20-lyase activity, only occurs in the zona reticularis and gonads. The specificity of the second reaction is due to the interaction with the haem-protein cytochrome b5. Surprisingly, cytochrome b5 and cytochrome P450 oxidoreductase have overlapping sites of interaction on the surface of P450c17. This poses the question as to how cytochrome b5 and cytochrome P450 oxidoreductase interact with P450c17 structurally, functionally and physiologically? This conundrum can be resolved based on the observation that P450c17 can homo-dimerise. A homodimer would allow cytochrome P450 oxidoreductase to bind to one P450c17 monomer of the P450c17 homodimer whilst cytochrome b5 could bind to the other P450c17 monomer simultaneously at the surfaces distal to the dimer interface. This structure is likely to be dynamic in vivo. Our modelling predicts that the proteins can assemble as a stable tetramer and is fully consistent with extensive experimental data that have been published over the last two decades. Predictions derived from this structural model are currently being tested by a range of in vitro and in vivo experimental approaches.