Identification of a sporozoite-specific antigen from Toxoplasma gondii

Reduction of risk for human and food animal infection with Toxoplasma gondii is hampered by the lack of epidemiological data documenting the predominant routes of infection (oocyst vs. tissue cyst consumption) in horizontally transmitted toxoplasmosis. Existing serological assays can determine previous exposure to the parasite, but not the route of infection. We have used difference gel electrophoresis, in combination with tandem mass spectroscopy and Western blot, to identify a sporozoite-specific protein (T. gondii embryogenesis-related protein [TgERP]), which elicited antibody and differentiated oocyst- versus tissue cyst-induced infection in pigs and mice. The recombinant protein was selected from a cDNA library constructed from T. gondii sporozoites; this protein was used in Western blots and probed with sera from T. gondii -infected humans. Serum antibody to TgERP was detected in humans within 6-8 mo of initial oocyst-acquired infection. Of 163 individuals in the acute stage of infection (anti- T. gondii IgM detected in sera, or < 30 in the IgG avidity test), 103 (63.2%) had detectable antibodies that reacted with TgERP. Of 176 individuals with unknown infection route and in the chronic stage of infection (no anti- T. gondii IgM detected in sera, or > 30 in the IgG avidity test), antibody to TgERP was detected in 31 (17.6%). None of the 132 uninfected individuals tested had detectable antibody to TgERP. These data suggest that TgERP may be useful in detecting exposure to sporozoites in early T. gondii infection and implicates oocysts as the agent of infection.     

Identification of INSL5, a new member of the insulin superfamily.

A new member of the insulin gene superfamily (INSL5) was identified by searching EST databases for the presence of the conserved insulin B-chain cysteine motif. Human and murine INSL5 are both polypeptides of 135 amino acids, matching the classical signature of the insulin superfamily. Through the B- and A-chain regions, human INSL5 has 48% identity to shark relaxin, 40% identity to human relaxin, and 34% identity to human Leydig insulin-like factor. Northern blot analysis detected expression of human INSL5 in rectal, colon, and uterine tissue and of murine INSL5 only in thymic tissue. Using quantitative RT-PCR, expression of murine INSL5 was detected in the highest quantity in colon followed by thymus, and minimal expression was seen in testis. By radiation hybrid mapping and the use of surrounding markers, human INSL5 maps to chromosome 1 in the 1p31.1 to 1p22.3 region.     

Identification of a novel member (GDF-1) of the transforming growth factor-beta superfamily.

A cDNA clone encoding a new member (designated GDF-1) of the transforming growth factor-beta (TGF beta) superfamily was isolated from a library prepared from day 8.5 mouse embryos. The nucleotide sequence of GDF-1 predicts a protein of 357 amino acids with a mol wt of 38,600. The sequence contains a pair of arginine residues at positions 236-237, which is likely to represent a site for proteolytic processing. The C-terminus following the presumed dibasic cleavage site shows significant homology with the known members of the TGF beta superfamily, matching the other family members at all of the invariant positions, including the seven cysteine residues with their characteristic spacing. GDF-1 is most homologous to Xenopus Vg-1 (52%), but is not likely to be the murine homolog of Vg-1. In vitro translation experiments were consistent with GDF-1 being a secreted glycoprotein. Genomic Southern analysis indicated that GDF-1 may be highly conserved across species. These results suggest that GDF-1 is most likely an extracellular factor mediating cell differentiation events during embryonic development.     

Seminal RNase: a unique member of the ribonuclease superfamily

The RNase found in bull semen, although a member of the mammalian superfamily of ribonucleases, possesses some unusual properties. Besides its unique structure and enzymic properties, it displays antispermatogenic, antitumor and immunosuppressive activities. Seminal RNase belongs to an interesting group of RNases, the RISBASES (RIbonucleases with Special, i.e. non catalytic, Biological Actions) other members of which include angiogenin, selectively neurotoxic RNases, a lectin and the self-incompatibility factors from a flowering plant.     

DNase II is a member of the phospholipase D superfamily

MOTIVATION: DNase II is an endodeoxyribonuclease involved in apoptosis and essential for the mammalian development. Despite the understanding of biochemical properties of this enzyme, its structure and relationships to other protein families remain unknown. RESULTS: Using protein fold-recognition we found that DNase II exhibits a catalytic domain common to the phospholipase D superfamily. Our model explains the available experimental data and provides the first structural platform for sequence-function analyses of this important nuclease.     

KtrB, a member of the superfamily of K+ transporters

KtrB is the K(+)-translocating subunit of the K(+)-uptake system KtrAB from bacteria. It is a member of the superfamily of K(+)transporters (SKT proteins) with other sub-families occurring in archaea, bacteria, fungi, plants and trypanosomes. SKT proteins may have originated from small K(+) channels by at least two gene duplication and two gene fusion events. They contain four covalently linked M(1)PM(2) domains, in which M(1) and M(2) stand for transmembrane stretches, and P for a P-loop, which folds back from the external medium into the membrane. SKT proteins distinguish themselves in two important aspects from K(+) channels: first, with just one conserved glycine residue in their P-loops they contain a much simpler K(+)-selectivity filter sequence than K(+) channels with their conserved Thr-Val-Gly-Tyr-Gly sequence. Secondly, the middle part M(2C2) from the long transmembrane stretch M(2C) of KtrB from the bacterium Vibrio alginolyticus forms a gate inside the membrane, which prevents K(+) permeation to the cytoplasm. Beside the mechanism of K(+) transport via KtrB and other SKT proteins existing hypotheses of how the KtrA protein regulates the K(+)-transport activity of KtrB are discussed.     

Mechanisms for variability in a member of the scavenger-receptor cysteine-rich superfamily

 This study reports a molecular analysis of pig WC1, a new member of the scavenger-receptor cysteine-rich (SRCR) superfamily. The pig WC1 contains up to six extra-cellular SRCR domains, highly homologous to other members of the family. However, the striking feature of the WC1 gene, as for its cattle and sheep homologues, is that it is present as a multigene family showing extensive sequence diversity, for both DNA and predicted protein sequence. The basis of this diversity was examined and was shown to be attributable to several different causes. These included single base-pair changes within SRCR domains, the optional usage of whole domains or exons, including a SRCR domain and the proximal “hinge” region, and alternative isoforms of the putative cytoplasmic tail. These results suggest that WC1 may code for a new, though more primitive type of antigen recognition structure specific for γ/δ T cells. Received: 12 November 1996 / Received: 10 March 1997     

The PYRIN domain: a member of the death domain-fold superfamily

PYRIN domains were identified recently as putative protein-protein interaction domains at the N-termini of several proteins thought to function in apoptotic and inflammatory signaling pathways. The approximately 95 residue PYRIN domains have no statistically significant sequence homology to proteins with known three-dimensional structure. Using secondary structure prediction and potential-based fold recognition methods, however, the PYRIN domain is predicted to be a member of the six-helix bundle death domain-fold superfamily that includes death domains (DDs), death effector domains (DEDs), and caspase recruitment domains (CARDs). Members of the death domain-fold superfamily are well established mediators of protein-protein interactions found in many proteins involved in apoptosis and inflammation, indicating further that the PYRIN domains serve a similar function. An homology model of the PYRIN domain of CARD7/DEFCAP/NAC/NALP1, a member of the Apaf-1/Ced-4 family of proteins, was constructed using the three-dimensional structures of the FADD and p75 neurotrophin receptor DDs, and of the Apaf-1 and caspase-9 CARDs, as templates. Validation of the model using a variety of computational techniques indicates that the fold prediction is consistent with the sequence. Comparison of a circular dichroism spectrum of the PYRIN domain of CARD7/DEFCAP/NAC/NALP1 with spectra of several proteins known to adopt the death domain-fold provides experimental support for the structure prediction.     

A common genetic variant in the neurexin superfamily member CNTNAP2 increases familial risk of autism

Autism is a childhood neuropsychiatric disorder that, despite exhibiting high heritability, has largely eluded efforts to identify specific genetic variants underlying its etiology. We performed a two-stage genetic study in which genome-wide linkage and family-based association mapping was followed up by association and replication studies in an independent sample. We identified a common polymorphism in contactin-associated protein-like 2 (CNTNAP2), a member of the neurexin superfamily, that is significantly associated with autism susceptibility. Importantly, the genetic variant displays a parent-of-origin and gender effect recapitulating the inheritance of autism.     

The SRS superfamily of Toxoplasma surface proteins

The surface of the protozoan parasite Toxoplasma gondii is coated with developmentally expressed, glycosylphosphatidylinositol-linked proteins structurally related to the highly immunogenic surface antigen SAG1. Collectively, these surface antigens are known as the SRS (SAG1-related sequences) superfamily of proteins. SRS proteins are thought to mediate attachment to host cells and activate host immunity to regulate the parasite's virulence. To better understand the number, evolution and developmental expression of SRS genes, this study has bioinformatically identified 161 unique SRS DNA sequences present in the T. gondii type II Me49 genome. The SRS superfamily of sequences phylogenetically bifurcates into two subfamilies, the prototypic members being SAG1 and SAG2A, respectively. Paralogous SRS sequences are 24-99% identical, are tandemly arrayed throughout the genome, and are present on most, if not all, chromosomes. All 11 SRS sequences on chromosomes Ia and Ib are clustered at sub-telomeric expression sites. Messenger RNA expression in the majority of SRS sequences for which multiple Expressed Sequence Tags exist is developmentally regulated. A consensus nucleotide sequence surrounding both the splice acceptor and donor sites was identified in those SRS sequences possessing an intron. Genotypic differences among SRS sequences are present at several loci (e.g. the absence of SAG5B, the truncation of SAG2D in Me49 compared with RH) indicating that different genotypes possess distinct sets of SRS sequences. Orthologous genes are restricted to tissue-dwelling coccidia (Neospora, Sarcocystis) with no related sequences present in other more distant apicomplexa such as Eimeria, Cryptosporidia, and Plasmodium spp.     

Homo-dimeric spherulin 3a: a single-domain member of the beta gamma-crystallin superfamily

The beta gamma-crystallin superfamily of eye lens proteins comprises a class of structurally related members with a wide variety of different functions. Common features of these proteins are 1. the Greek-key motif of antiparallel beta-sheets, called the crystallin fold, and 2. the high intrinsic long-term stability. Spherulin 3a (S3a), a dormant protein from the spherules of Physarum polycephalum, is the only known single-domain protein within the beta gamma-crystallin family. Based on sequence homology and 'domain swapping', it has been proposed to represent an evolutionary ancestor of present-day eye lens crystallins. Since S3a is highly expressed in spherulating plasmodia of P. polycephalum under a variety of stress conditions, it can be assumed that the protein may serve as a compatible solute in the cytosol of the slime mold. In order to investigate the stability and other physicochemical properties of a single-domain all-beta protein, we isolated natural S3a. For the large-scale purification, the recombinant protein was cloned and expressed in Escherichia coli. The detailed spectral and biochemical analysis proved the recombinant protein to be authentic. In its native form, S3a is dimeric. Due to its exposed cysteine residues (Cys4), in the absence of reducing agents intermolecular disulfide cross-linking leads to the formation of higher oligomers. In order to preserve the native quaternary structure without aggregation artifacts in denaturation/renaturation experiments, the Cys4-->Ser mutant (S3a C4S) was produced. Both the wild-type protein and its mutant are indistinguishable in their physicochemical properties. At pH 3 - 4, both proteins form a stable compact intermediate (A-state). Concentration-dependent thermal and chemical denaturation showed that the equilibrium unfolding of S3a obeys the simple two-state model with no significant occurrence of folding intermediates.     

Characterization of amalgam: a member of the immunoglobulin superfamily from Drosophila

The immunoglobulin superfamily is a diverse group of proteins that are involved in various aspects of cell surface recognition. Here, we report the characterization of amalgam (ama), a gene in the Antennapedia complex (ANT-C) of D. melanogaster that exhibits amino acid similarity to vertebrate neural cell adhesion molecules and other members of the immunoglobulin superfamily. The putative 333 amino acid ama protein consists of a signal sequence, three immunoglobulin-like domains, and a short slightly hydrophobic carboxy-terminal region. Antibodies against the ama protein reveal that it accumulates on the surface of various mesodermal and neural cells during embryogenesis. The function of this protein remains elusive, as no mutations have been recovered for ama during saturation EMS mutagenesis of this chromosomal region.     

MAGE-F1, a novel ubiquitously expressed member of the MAGE superfamily

Most known members of the MAGE superfamily are expressed in tumors, testis and fetal tissues, which has been described as a cancer/testis or "CT" expression pattern. We have identified a novel member of this superfamily, MAGE-F1, which is expressed in all adult and fetal tissues tested. In addition to normal tissues, MAGE-F1 is expressed in many tumor types including ovarian, breast, cervical, melanoma and leukemia. MAGE-F1 is encoded on chromosome 3, identifying a sixth chromosomal location for a MAGE superfamily gene. The coding region of MAGE-F1 is contained within a single exon and includes a microsatellite repeat. Sequence analysis and expression profiles define a new class of ubiquitously expressed MAGE superfamily genes that includes MAGE-F1, MAGE-D1, MAGE-D2/JCL-1 and NDN. The finding that several MAGE genes are ubiquitously expressed suggests a role for MAGE encoded proteins in normal cell physiology. Furthermore, potential cross-reactivity to these ubiquitously expressed MAGE gene products should be considered in the design of MAGE-targeted immunotherapies for cancer.