Domains of invasion organelle proteins from apicomplexan parasites are homologous with the Apple domains of blood coagulation factor XI and plasma pre-kallikrein and are members of the PAN module superfamily

Micronemes are specialised organelles, found in all apicomplexan parasites, which secrete molecules that are essential for parasite attachment to and invasion of host cells. Regions of several microneme proteins have sequence similarity to the Apple domains (A-domains) of blood coagulation factor XI (FXI) and plasma pre-kallikrein (PK). We have used mass spectrometry on a recombinant-expressed, putative A-domain from the microneme protein EtMIC5 from Eimeria tenella, to demonstrate that three intramolecular disulphide bridges are formed. These bridges are analogous to those that stabilise A-domains in FXI and PK. The data confirm that the apicomplexan domains are structural homologues of A-domains and are therefore novel members of the PAN module superfamily, which also includes the N-terminal domains of members of the plasminogen/hepatocyte growth factor family. The role of A-domains/PAN modules in apicomplexan parasites is not known, but their presence in the microneme suggests that they may be important for mediating protein-protein or protein-carbohydrate interactions during parasite attachment and host cell invasion.     

Solution structure of a PAN module from the apicomplexan parasite Eimeria tenella

Micronemes, specialised organelles found in all apicomplexan parasites, secrete molecules that are essential for parasite attachment and invasion of host cells. EtMIC5 is one such microneme protein that contains eleven tandemly repeating modules. These modules have homology with the PAN module superfamily. Members of this family are found in blood clotting proteins, some growth factors and some nematode proteins. This paper presents the structure of the 9^th PAN module in EtMIC5, determined using high resolution NMR. The structure shows similarities to and some differences from the N-terminal module of hepatocyte growth factor (HGF), the only previous member of the PAN family with known structure. AbbreviationsNMR – nuclear magnetic resonance; NOE – nuclear Overhauser enhancement; NOESY – NOE spectroscopy; COSY – correlated spectroscopy; TOCSY – total correlated spectroscopy; HSQC – hetero nuclear single quantum coherence; HMQC-J – hetero nuclear multiple quantum coherence-J coupling; MICs – microneme proteins; EtMIC5 – a microneme protein from Eimeria tenella; Apple9 – the ninth Apple repeat of EtMIC5; FXI – blood coagulation factor XI; PK – plasma prekallikrein; HGF – hepatocyte growth factor.     

Extra domains in secondary transport carriers and channel proteins

"Extra" domains in members of the families of secondary transport carrier and channel proteins provide secondary functions that expand, amplify or restrict the functional nature of these proteins. Domains in secondary carriers include TrkA and SPX domains in DASS family members, DedA domains in TRAP-T family members (both of the IT superfamily), Kazal-2 and PDZ domains in OAT family members (of the MF superfamily), USP, IIA(Fru) and TrkA domains in ABT family members (of the APC superfamily), ricin domains in OST family members, and TrkA domains in AAE family members. Some transporters contain highly hydrophilic domains consisting of multiple repeat units that can also be found in proteins of dissimilar function. Similarly, transmembrane alpha-helical channel-forming proteins contain unique, conserved, hydrophilic domains, most of which are not found in carriers. In some cases the functions of these domains are known. They may be ligand binding domains, phosphorylation domains, signal transduction domains, protein/protein interaction domains or complex carbohydrate-binding domains. These domains mediate regulation, subunit interactions, or subcellular targeting. Phylogenetic analyses show that while some of these domains are restricted to closely related proteins derived from specific organismal types, others are nearly ubiquitous within a particular family of transporters and occur in a tremendous diversity of organisms. The former probably became associated with the transporters late in the evolutionary process; the latter probably became associated with the carriers much earlier. These domains can be located at either end of the transporter or in a central region, depending on the domain and transporter family. These studies provide useful information about the evolution of extra domains in channels and secondary carriers and provide novel clues concerning function.     

Extra domains in secondary transport carriers and channel proteins

“Extra” domains in members of the families of secondary transport carrier and channel proteins provide secondary functions that expand, amplify or restrict the functional nature of these proteins. Domains in secondary carriers include TrkA and SPX domains in DASS family members, DedA domains in TRAP-T family members (both of the IT superfamily), Kazal-2 and PDZ domains in OAT family members (of the MF superfamily), USP, IIA^Fru and TrkA domains in ABT family members (of the APC superfamily), ricin domains in OST family members, and TrkA domains in AAE family members. Some transporters contain highly hydrophilic domains consisting of multiple repeat units that can also be found in proteins of dissimilar function. Similarly, transmembrane α-helical channel-forming proteins contain unique, conserved, hydrophilic domains, most of which are not found in carriers. In some cases the functions of these domains are known. They may be ligand binding domains, phosphorylation domains, signal transduction domains, protein/protein interaction domains or complex carbohydrate-binding domains. These domains mediate regulation, subunit interactions, or subcellular targeting. Phylogenetic analyses show that while some of these domains are restricted to closely related proteins derived from specific organismal types, others are nearly ubiquitous within a particular family of transporters and occur in a tremendous diversity of organisms. The former probably became associated with the transporters late in the evolutionary process; the latter probably became associated with the carriers much earlier. These domains can be located at either end of the transporter or in a central region, depending on the domain and transporter family. These studies provide useful information about the evolution of extra domains in channels and secondary carriers and provide novel clues concerning function.     

Solution structure and dynamics of a prototypical chordin-like cysteine-rich repeat (von Willebrand Factor type C module) from collagen IIA

Chordin-like cysteine-rich (CR) repeats (also referred to as von Willebrand factor type C (VWC) modules) have been identified in approximately 200 extracellular matrix proteins. These repeats, named on the basis of amino acid conservation of 10 cysteine residues, have been shown to bind members of the transforming growth factor-beta (TGF-beta) superfamily and are proposed to regulate growth factor signaling. Here we describe the intramolecular disulfide bonding, solution structure, and dynamics of a prototypical chordin-like CR repeat from procollagen IIA (CR(ColIIA)), which has been previously shown to bind TGF-beta1 and bone morphogenetic protein-2. The CR(ColIIA) structure manifests a two sub-domain architecture tethered by a flexible linkage. Initial structures were calculated using RosettaNMR, a de novo prediction method, and final structure calculations were performed using CANDID within CYANA. The N-terminal region contains mainly beta-sheet and the C-terminal region is more irregular with the fold constrained by disulfide bonds. Mobility between the N- and C-terminal sub-domains on a fast timescale was confirmed using NMR relaxation measurements. We speculate that the mobility between the two sub-domains may decrease upon ligand binding. Structure and sequence comparisons have revealed an evolutionary relationship between the N-terminal sub-domain of the CR module and the fibronectin type 1 domain, suggesting that these domains share a common ancestry. Based on the previously reported mapping of fibronectin binding sites for vascular endothelial growth factor to regions containing fibronectin type 1 domains, we discuss the possibility that this structural homology might also have functional relevance.     

Friends and relations of the cystatin superfamily--new members and their evolution.

The cystatin "superfamily" encompasses proteins that contain multiple cystatin-like sequences. Some of the members are active cysteine protease inhibitors, while others have lost or perhaps never acquired this inhibitory activity. In recent years, several new members of the superfamily have characterized, including proteins from insects and plants. Based on partial amino acid homology, new members, such as the invariant chain (Ii), and the transforming growth factor-beta receptor type II (TGF-beta receptor II) may, in fact, represent members of an emerging family within the superfamily that may have used some common building blocks to form functionally diverse proteins. Cystatin super-family members have been found throughout evolution and members of each family of the superfamily are present in mammals today. In this review, the new and older, established members of the family are arranged into a possible evolutionary order, based on sequence homology and functional similarities.     

The bile/arsenite/riboflavin transporter (BART) superfamily

Secondary transmembrane transport carriers fall into families and superfamilies allowing prediction of structure and function. Here we describe hundreds of sequenced homologues that belong to six families within a novel superfamily, the bile/arsenite/riboflavin transporter (BART) superfamily, of transport systems and putative signalling proteins. Functional data for members of three of these families are available, and they transport bile salts and other organic anions, the bile acid:Na(+) symporter (BASS) family, inorganic anions such as arsenite and antimonite, the arsenical resistance-3 (Acr3) family, and the riboflavin transporter (RFT) family. The first two of these families, as well as one more family with no functionally characterized members, exhibit a probable 10 transmembrane spanner (TMS) topology that arose from a tandemly duplicated 5 TMS unit. Members of the RFT family have a 5 TMS topology, and are homologous to each of the repeat units in the 10 TMS proteins. The other two families [sensor histidine kinase (SHK) and kinase/phosphatase/synthetase/hydrolase (KPSH)] have a single 5 TMS unit preceded by an N-terminal TMS and followed by a hydrophilic sensor histidine kinase domain (the SHK family) or catalytic domains resembling sensor kinase, phosphatase, cyclic di-GMP synthetase and cyclic di-GMP hydrolase catalytic domains, as well as various noncatalytic domains (the KPSH family). Because functional data are not available for members of the SHK and KPSH families, it is not known if the transporter domains retain transport activity or have evolved exclusive functions in molecular reception and signal transmission. This report presents characteristics of a unique protein superfamily and provides guides for future studies concerning structural, functional and mechanistic properties of its constituent members.     

Structural localization of disease-associated sequence variations in the NACHT and LRR domains of PYPAF1 and NOD2

Several autoinflammatory diseases with distinct clinical manifestations have been associated with sequence variations in the gene products PYPAF1/CIAS1 and NOD2/CARD15. Both proteins belong to the PYD/CARD-containing family of apoptosis regulators and activators of pro-inflammatory caspases. To gain insight into the dysfunctional role of sequence alterations, we assembled a structure-based multiple sequence alignment of family members and related proteins. This allowed us to analyze the putative effect of the alterations on the function of nucleotide-binding (NACHT) and leucine-rich repeat (LRR) domains shared by the family members. In support of this analysis, we carefully selected template structures for the NACHT and LRR domains and mapped the genetic variations onto 3D domain models. Additionally, we propose a model of the NACHT and LRR domain complex. Our study revealed that many of the disease-associated sequence variants are located close to highly conserved sequence regions of functional relevance and are spatially adjacent in the predicted 3D structure. The implications on the domain functions such as NTP-hydrolysis or oligomerization are discussed.     

Mapping of the physical interaction between the intracellular domains of an inwardly rectifying potassium channel, Kir6.2

The amino-terminal and carboxyl-terminal domains of inwardly rectifying potassium (Kir) channel subunits are both intracellular. There is increasing evidence that both of these domains are required for the regulation of Kir channels by agents such as G-proteins and nucleotides. Kir6.2 is the pore-forming subunit of the ATP-sensitive K(+) (K(ATP)) channel. Using an in vitro protein-protein interaction assay, we demonstrate that the two intracellular domains of Kir6.2 physically interact with each other, and we map a region within the N terminus that is responsible for this interaction. "Cross-talk" through this interaction may explain how mutations in either the N or C terminus can influence the intrinsic ATP-sensitivity of Kir6.2. Interestingly, the "interaction domain" is highly conserved throughout the superfamily of Kir channels. The N-terminal interaction domain of Kir6.2 can also interact with the C terminus of both Kir6.1 and Kir2.1. Furthermore, a mutation within the conserved region of the N-terminal interaction domain, which disrupts its interaction with the C terminus, severely compromised the ability of both Kir6.2 and Kir2.1 to form functional channels, suggesting that this interaction may be a feature common to all members of the Kir family of potassium channels.     

Functions and functional domains of the GTPase Cdc42p

Cdc42p, a Rho family GTPase of the Ras superfamily, is a key regulator of cell polarity and morphogenesis in eukaryotes. Using 37 site-directed cdc42 mutants, we explored the functions and interactions of Cdc42p in the budding yeast Saccharomyces cerevisiae. Cytological and genetic analyses of these cdc42 mutants revealed novel and diverse phenotypes, showing that Cdc42p possesses at least two distinct essential functions and acts as a nodal point of cell polarity regulation in vivo. In addition, mapping the functional data for each cdc42 mutation onto a structural model of the protein revealed as functionally important a surface of Cdc42p that is distinct from the canonical protein-interacting domains (switch I, switch II, and the C terminus) identified previously in members of the Ras superfamily. This region overlaps with a region (alpha5-helix) recently predicted by structural models to be a specificity determinant for Cdc42p-protein interactions.     

Interaction interfaces of protein domains are not topologically equivalent across families within superfamilies: Implications for metabolic and signaling pathways

Using a data set of aligned protein domain superfamilies of known three-dimensional structure, we compared the location of interdomain interfaces on the tertiary folds between members of distantly related protein domain superfamilies. The data set analyzed is comprised of interdomain interfaces, with domains occurring within a polypeptide chain and those between two polypeptide chains. We observe that, in general, the interfaces between protein domains are formed entirely in different locations on the tertiary folds in such pairs. This variation in the location of interface happens in protein domains involved in a wide range of functions, such as enzymes, adapters, and domains that bind protein ligands, or cofactors. While basic biochemical functionality is preserved at the domain superfamily level, the effect of biochemical function on protein assemblies is different in these protein domains related by superfamily. The divergence between proteins, in most cases, is coupled with domain recruitment, with different modes of interaction with the recruited domain. This is in complete contrast to the observation that in closely related homologous protein domains, almost always the interaction interfaces are topologically equivalent. In a small subset of interacting domains within proteins related by remote homology, we observe that the relative positioning of domains with respect to one another is preserved. Based on the analysis of multidomain proteins of known or unknown structure, we suggest that variation in protein-protein interactions in members within a superfamily could serve as diverging points in otherwise parallel metabolic or signaling pathways. We discuss a few representative cases of diverging pathways involving domains in a superfamily.     

Modes of evolution in the protease and kringle domains of the plasminogen-prothrombin family

Phylogenetic analysis of protease domains of the vertebrate plasminogen-prothrombin family revealed two major subfamilies: (1) a subfamily containing macrophage-stimulating protein (MSP), hepatocyte growth factor (HGF), plasminogen, and apolipoprotein(a) (APOA); and (2) a subfamily containing prothrombin, HGF activator, and plasminogen activators. There was evidence that these two subfamilies diverged prior to the divergence of amphibians and amniotes. The phylogeny indicated a close relationship of APOA from the European hedgehog, rhesus monkey, and human with plasminogen. Phylogenetic analysis of repeated kringle domains supported the hypothesis that APOA evolved independently in hedgehog and primates through numerous duplications of different kringle domains of the ancestral plasminogen. Phylogenies of kringle domains revealed two modes of evolution: (1) a conservative mode, whereby duplication of kringle domains occurred prior to cladogenesis and the same kringle structure has been maintained in different lineages (exemplified by plasminogen and prothrombin); and (2) a concerted mode, whereby kringle domains have duplicated since cladogenesis and thus orthologous relationships do not exist between kringles of different lineages (exemplified by APOA).     

Evolution of structure and function in the o-succinylbenzoate synthase/N-acylamino acid racemase family of the enolase superfamily

Understanding how proteins evolve to provide both exquisite specificity and proficient activity is a fundamental problem in biology that has implications for protein function prediction and protein engineering. To study this problem, we analyzed the evolution of structure and function in the o-succinylbenzoate synthase/N-acylamino acid racemase (OSBS/NAAAR) family, part of the mechanistically diverse enolase superfamily. Although all characterized members of the family catalyze the OSBS reaction, this family is extraordinarily divergent, with some members sharing <15% identity. In addition, a member of this family, Amycolatopsis OSBS/NAAAR, is promiscuous, catalyzing both dehydration and racemization. Although the OSBS/NAAAR family appears to have a single evolutionary origin, no sequence or structural motifs unique to this family could be identified; all residues conserved in the family are also found in enolase superfamily members that have different functions. Based on their species distribution, several uncharacterized proteins similar to Amycolatopsis OSBS/NAAAR appear to have been transmitted by lateral gene transfer. Like Amycolatopsis OSBS/NAAAR, these might have additional or alternative functions to OSBS because many are from organisms lacking the pathway in which OSBS is an intermediate. In addition to functional differences, the OSBS/NAAAR family exhibits surprising structural variations, including large differences in orientation between the two domains. These results offer several insights into protein evolution. First, orthologous proteins can exhibit significant structural variation, and specificity can be maintained with little conservation of ligand-contacting residues. Second, the discovery of a set of proteins similar to Amycolatopsis OSBS/NAAAR supports the hypothesis that new protein functions evolve through promiscuous intermediates. Finally, a combination of evolutionary, structural, and sequence analyses identified characteristics that might prime proteins, such as Amycolatopsis OSBS/NAAAR, for the evolution of new activities.     

Mapping the hyaluronan-binding site on the link module from human tumor necrosis factor-stimulated gene-6 by site-directed mutagenesis

Link modules are hyaluronan-binding domains found in extracellular proteins involved in matrix assembly, development, and immune cell migration. Previously we have expressed the Link module from the inflammation-associated protein tumor necrosis factor-stimulated gene-6 (TSG-6) and determined its tertiary structure in solution. Here we generated 21 Link module mutants, and these were analyzed by nuclear magnetic resonance spectroscopy and a hyaluronan-binding assay. The individual mutation of five amino acids, which form a cluster on one face of the Link module, caused large reductions in functional activity but did not affect the Link module fold. This ligand-binding site in TSG-6 is similar to that determined previously for the hyaluronan receptor, CD44, suggesting that the location of the interaction surfaces may also be conserved in other Link module-containing proteins. Analysis of the sequences of TSG-6 and CD44 indicates that the molecular details of their association with hyaluronan are likely to be significantly different. This comparison identifies key sequence positions that may be important in mediating hyaluronan binding, across the Link module superfamily. The use of multiple sequence alignment and molecular modeling allowed the prediction of functional residues in link protein, and this approach can be extended to all members of the superfamily.     

Molecular cloning of SCDGF-B, a novel growth factor homologous to SCDGF/PDGF-C/fallotein

Spinal cord-derived growth factor (SCDGF)/platelet-derived growth factor (PDGF)-C/fallotein has a unique two-domain structure, as it contains two regions homologousto CUB and PDGF/vascular endothelial growth factor (VEGF) domains. In this study, we isolateda novel gene homologous to SCDGF/PDGF-C/fallotein, and named SCDGF-B. The culture supernatant of CHO-K1 cells stably transfected with SCDGF-B showed mitogenic activity as SCDGF/PDGF-C/fallotein did. Although SCDGF-B and SCDGF/PDGF-C/fallotein might be the members of the PDGF/VEGF superfamily of growth factors, they were categorized into a new subfamily in addition to PDGF and VEGF subfamilies.     

Structural insights into group II TRP channels

The seven members of the TRP channel superfamily are divided into two main groups with five members comprising group I (TRPC/V/M/N/A) and TRPML (TRP MucoLipin) and TRPP (TRP Polycystin) making up group II. Group II channels share a high sequence homology on their transmembrane domains and are distinct from group I members as they contain a large luminal/extracellular domain between transmembrane helix 1 (S1) and S2. Since 2016, there are more than ten research papers reporting various structures of group II channels by either cryo-EM or X-ray crystallography. These studies along with recent functional analysis by the other groups have considerably strengthened our knowledge on TRPML and TRPP channels. In this review, we summarize and discuss these reports providing molecular insights into the group II TRP channel family.