Conserved classes of homeodomains in Schistosoma mansoni, an early bilateral metazoan.

Genes containing a homeobox can be divided into classes based on the distinctive peptide sequences of their diverged homeodomains. Many of these classes, including Antennapedia, engrailed and paired, are strongly conserved in higher multicellular animals, but have not previously been found in platyhelminths, the flatworms which represent the most primitive bilateral metazoans. We have screened cDNA libraries of the platyhelminth Schistosoma mansoni using a degenerate oligonucleotide derived from the third helix of the homeodomain, and have identified numerous schistosome homeobox-containing sequences, including members of the Antennapedia, engrailed and paired classes. The schistosome homeodomain sequences are more similar to the higher animals sequences in their respective classes than they are to each other, indicating that the establishment of these three distinctive classes is at least as ancient as the flatworms. Our data suggest that the ancestral functions of the Antennapedia, engrailed and paired classes involve fundamental features of all bilateral metazoan development. The putative full-length coding sequence of the S. mansoni en homologue is presented.     

Members of TALE and WUS subfamilies of homeodomain proteins with potentially important functions in development form dimers within each subfamily in rice

Transacting factors often form homo- and heterodimers and regulate various targets, the type of regulation depending on the dimeric combination. The WUS and TALE subfamilies are two atypical homeodomains in plants. A homeodomain mediates sequence-specific binding to its target DNA and usually consists of 60 amino acid residues, whereas atypical homeodomains have extra amino acid residues in the well-conserved region. The genes OsWUS and OsPRS, which encode atypical homeodomain proteins from the WUS subfamily, and OsBEL and OSH15, which encode those from the TALE subfamily, were isolated from rice and tested for their interactions by yeast two-hybrid analysis. OsWUS and OsPRS formed homodimers and formed heterodimers with each other but did not form dimers with the TALE family homeodomain proteins OSH15 or OsBEL. Likewise, OSH15 and OsBEL formed homodimers and heterodimers but did not form dimers with the WUS family homeodomain proteins OsWUS and OsPRS. These findings suggest that the combinations of dimers are well correlated with the classification of these proteins on the basis of sequence similarity. RT-PCR analysis revealed that expression of OsWUS and OsPRS was detected in the same organs, namely floral buds, roots, and suspension cells. Therefore, it is possible that the proteins encoded by both of these genes function as homo- and heterodimers in planta. These results suggest that, during the evolution of these subfamilies, various combinations of dimers within proteins encoded by paralogous genes were formed and generated independent regulatory networks that enabled complex patterns of plant development.     

Phylogenetic relationships and evolution of the KNOTTED class of plant homeodomain proteins.

Knotted-like (KNOX) proteins constitute a group of homeodomain proteins involved in pattern formation in developing tissues of angiosperms and other green plants. We conducted phylogenetic analyses of nucleotide and amino acid sequences of all known KNOX proteins in order to examine their evolution. Our analyses reveal two groups of KNOX proteins, classes I and II. Dicot and monocot sequences occur in both classes, indicating that the protein classes arose prior to the origin of the monocots. A conifer (Picea) sequence is nested within class I, suggesting that there are likely to be other copies of KNOX genes in this and other conifers. The orthology of several grass genes (including Zea Kn1, ZMKN1) is strongly supported by phylogenetic and synteny analyses. However, no compelling evidence supports the hypothesis of orthology previously proposed for several dicot genes and ZMKN1. Analysis of expression patterns suggests that the ancestral KNOX gene was expressed in all plant parts and that the propensity to be downregulated in roots and leaves evolved in the class I genes.     

Origin of the paired domain

Pax proteins play a diverse role in early animal development and contain the characteristic paired domain, consisting of two conserved helix-turn-helix motifs. In many Pax proteins the paired domain is fused to a second DNA binding domain of the paired-like homeobox family. By amino acid sequence alignments, secondary structure prediction, 3D-structure comparison, and phylogenetic reconstruction, we analyzed the relationship between Pax proteins and members of the Tc1 family of transposases, which possibly share a common ancestor with Pax proteins. We suggest that the DNA binding domain of an ancestral transposase (proto-Pax transposase) was fused to a homeodomain shortly after the emergence of metazoans about one billion years ago. Using the transposase sequences as an outgroup we reexamined the early evolution of the Pax proteins. Our novel evolutionary scenario features a single homeobox capturing event and an early duplication of Pax genes before the divergence of porifera, indicating a more diverse role of Pax proteins in primitive animals than previously expected. Received: 16 February 2000 / Accepted: 13 August 2000     

PIRLs: a novel class of plant intracellular leucine-rich repeat proteins

Leucine-rich repeat (LRR) proteins feature tandem leucine-rich motifs that form a protein-protein interaction domain. Plants contain diverse classes of LRR proteins, many of which take part in signal transduction. We have identified a novel family of nine Arabidopsis LRR proteins that, based on predicted intracellular location and LRR motif consensus sequence, are related to Ras-binding LRR proteins found in signaling complexes in animals and yeast. This new class has been named plant intracellular Ras group-related LRR proteins (PIRLs). We have characterized PIRL cDNAs, rigorously defined gene and protein annotations, investigated gene family evolution and surveyed mRNA expression. While LRR regions suggested a relationship to Ras group LRR proteins, outside of their LRR domains PIRLs differed from Ras group proteins, exhibiting N- and C-terminal regions containing low complexity stretches and clusters of charged amino acids. PIRL genes grouped into three subfamilies based on sequence relationships and gene structures. Related gene pairs and dispersed chromosomal locations suggested family expansion by ancestral genomic or segmental duplications. Expression surveys revealed that all PIRL mRNAs are actively transcribed, with three expressed differentially in leaves, roots or flowers. These results define PIRLs as a distinct, plant-specific class of intracellular LRR proteins that probably mediate protein interactions, possibly in the context of signal transduction. T-DNA knock-out mutants have been isolated as a starting point for systematic functional analysis of this intriguing family.     

Problems Associated with the Identification of Proteins in Homologous Families: The Wool Keratin Family as a Case Study

The keratin proteins from wool can be divided into two classes: the intermediate filament proteins (IFPs) and the matrix proteins. Using peptide mass spectral fingerprinting it was possible to match spots to the known theoretical sequences of some IFPs in web-based databases, as enzyme digestion generated sufficient numbers of peptides from each spot to achieve this. In contrast, it was more difficult to obtain good matches for some of the lower molecular weight matrix proteins. Relatively few peaks were generated from tryptic digests of high-sulfur proteins because of their lower molecular weight and the absence of basic residues in the first two-thirds of the sequence. Their high sequence homology also means that generally only a few of these peptides could be considered to be unique identifiers for each protein. Nevertheless, it was still possible to uniquely identify some of these proteins, while the presence of two peptides in the matrix-assisted laser desorption/ionization time-of-flight mass spectrum allowed classification of other protein spots as being members of this family. Only one major peptide peak was generated by the high-glycine tyrosine proteins (HGTPs) and there were relatively few sequences available in web-based databases, limiting their identification to one HGTP family.     

The HopZ family of Pseudomonas syringae type III effectors require myristoylation for virulence and avirulence functions in Arabidopsis thaliana

Pseudomonas syringae utilizes the type III secretion system to translocate effector proteins into plant cells, where they can contribute to the pathogen's ability to infect and cause disease. Recognition of these effectors by resistance proteins induces defense responses that typically include a programmed cell death reaction called the hypersensitive response. The YopJ/HopZ family of type III effector proteins is a common family of effector proteins found in animal- and plant-pathogenic bacteria. The HopZ family in P. syringae includes HopZ1a(PsyA2), HopZ1b(PgyUnB647), HopZ1c(PmaE54326), HopZ2(Ppi895A) and HopZ3(PsyB728a). HopZ1a is predicted to be most similar to the ancestral hopZ allele and causes a hypersensitive response in multiple plant species, including Arabidopsis thaliana. Therefore, it has been proposed that host defense responses have driven the diversification of this effector family. In this study, we further characterized the hypersensitive response induced by HopZ1a and demonstrated that it is not dependent on known resistance genes. Further, we identified a novel virulence function for HopZ2 that requires the catalytic cysteine demonstrated to be required for protease activity. Sequence analysis of the HopZ family revealed the presence of a predicted myristoylation sequence in all members except HopZ3. We demonstrated that the myristoylation site is required for membrane localization of this effector family and contributes to the virulence and avirulence activities of HopZ2 and HopZ1a, respectively. This paper provides insight into the selective pressures driving virulence protein evolution by describing a detailed functional characterization of the diverse HopZ family of type III effectors with the model plant Arabidopsis.     

Characterization of a Novel Class of Interspersed LTR Elements in Primate Genomes: Structure, Genomic Distribution, and Evolution

Retrovirus-like sequences and their solitary (solo) long terminal repeats (LTRs) are common repetitive elements in eukaryotic genomes. We reported previously that the tandemly arrayed genes encoding U2 snRNA (the RNU2 locus) in humans and apes contain a solo LTR (U2-LTR) which was presumably generated by homologous recombination between the two LTRs of an ancestral provirus that is retained in the orthologous baboon RNU2 locus. We have now sequenced the orthologous U2-LTRs in human, chimpanzee, gorilla, orangutan, and baboon and examined numerous homologs of the U2-LTR that are dispersed throughout the human genome. Although these U2-LTR homologs have been collectively referred to as LTR13 in the literature, they do not display sequence similarity to any known retroviral LTRs; however, the structure of LTR13 closely resembles that of other retroviral LTRs with a putative promoter, polyadenylation signal, and a tandemly repeated 53-bp enhancer-like element. Genomic blotting indicates that LTR13 is primate-specific; based on sequence analysis, we estimate there are about 2,500 LTR13 elements in the human genome. Comparison of the primate U2-LTR sequences suggests that the homologous recombination event that gave rise to the solo U2-LTR occurred soon after insertion of the ancestral provirus into the ancestral U2 tandem array. Phylogenetic analysis of the LTR13 family confirms that it is diverse, but the orthologous U2-LTRs form a coherent group in which chimpanzee is closest to the humans; orangutan is a clear outgroup of human, chimpanzee, and gorilla; and baboon is a distant relative of human, chimpanzee, gorilla, and orangutan. We compare the LTR13 family with other known LTRs and consider whether these LTRs might play a role in concerted evolution of the primate RNU2 locus. Received: 29 September 1997 / Accepted: 16 January 1998     

The role of BEACH proteins in Dictyostelium

The BEACH family of proteins is a novel group of proteins with diverse roles in eukaryotic cells. The identifying feature of these proteins is the BEACH domain named after the founding members of this family, the mouse beige and the human Chediak–Higashi syndrome proteins. Although all BEACH proteins share a similar structural organization, they appear to have very distinct cellular roles, ranging from lysosomal traffic to apoptosis and cytokinesis. Very little is currently known about the function of most of these proteins, few binding-partner proteins have been identified, and no molecular mechanism for any of these proteins has been discovered. Thus, it is important to establish good model systems for the study of these novel proteins. Dictyostelium contains six BEACH proteins that can be classified into four subclasses. Two of them, LvsA and LvsB, have clearly distinct roles in the cell. LvsA is localized on the contractile vacuole membrane and is essential for cytokinesis and osmoregulation. LvsB is most similar in sequence to the mammalian beige/Chediak–Higashi syndrome proteins and shares with them a common function in lysosomal trafficking. Structural and functional analysis of these proteins in Dictyostelium will help elucidate the function of this enigmatic novel family of proteins .     

Classification and evolution of P-loop GTPases and related ATPases

Sequences and available structures were compared for all the widely distributed representatives of the P-loop GTPases and GTPase-related proteins with the aim of constructing an evolutionary classification for this superclass of proteins and reconstructing the principal events in their evolution. The GTPase superclass can be divided into two large classes, each of which has a unique set of sequence and structural signatures (synapomorphies). The first class, designated TRAFAC (after translation factors) includes enzymes involved in translation (initiation, elongation, and release factors), signal transduction (in particular, the extended Ras-like family), cell motility, and intracellular transport. The second class, designated SIMIBI (after signal recognition particle, MinD, and BioD), consists of signal recognition particle (SRP) GTPases, the assemblage of MinD-like ATPases, which are involved in protein localization, chromosome partitioning, and membrane transport, and a group of metabolic enzymes with kinase or related phosphate transferase activity. These two classes together contain over 20 distinct families that are further subdivided into 57 subfamilies (ancient lineages) on the basis of conserved sequence motifs, shared structural features, and domain architectures. Ten subfamilies show a universal phyletic distribution compatible with presence in the last universal common ancestor of the extant life forms (LUCA). These include four translation factors, two OBG-like GTPases, the YawG/YlqF-like GTPases (these two subfamilies also consist of predicted translation factors), the two signal-recognition-associated GTPases, and the MRP subfamily of MinD-like ATPases. The distribution of nucleotide specificity among the proteins of the GTPase superclass indicates that the common ancestor of the entire superclass was a GTPase and that a secondary switch to ATPase activity has occurred on several independent occasions during evolution. The functions of most GTPases that are traceable to LUCA are associated with translation. However, in contrast to other superclasses of P-loop NTPases (RecA-F1/F0, AAA+, helicases, ABC), GTPases do not participate in NTP-dependent nucleic acid unwinding and reorganizing activities. Hence, we hypothesize that the ancestral GTPase was an enzyme with a generic regulatory role in translation, with subsequent diversification resulting in acquisition of diverse functions in transport, protein trafficking, and signaling. In addition to the classification of previously known families of GTPases and related ATPases, we introduce several previously undetected families and describe new functional predictions.     

The three-dimensional structures of peptide methionine sulfoxide reductases: current knowledge and open questions

Methionine sulfoxides are easily formed in proteins exposed to reactive oxidative species commonly present in cells. Their reduction back to methionine residues is catalyzed by peptide methionine sulfoxide reductases. Although grouped in a unique family with respect to their biological function, these enzymes are divided in two classes named MsrA and MsrB, depending on the sulfoxide enantiomer of the substrate they reduce. This specificity-based classification differentiates enzymes which display no sequence homology. Several three-dimensional structures of peptide methionine sulfoxide reductases have been determined, so that members of both classes are known to date. These crystal structures are reviewed in this paper. The folds and active sites of MsrAs and MsrBs are discussed in the light of the methionine sulfoxide reductase sequence diversity.     

Six genes of the human connexin gene family coding for gap junctional proteins are assigned to four different human chromosomes

Connexin genes code for proteins that form cell-to-cell channels known as gap junctions. The genes for the known connexins 26, 32, 43, and 46 have been assigned to human chromosomes, 13, X, 6, and 13, respectively, by analysis of a panel of human-mouse somatic cell hybrids using rat cDNA probes. A pseudogene of connexin 43 that lacks an intron of the cx43 gene has been located on human chromosome 5. Furthermore, the genes of the two new connexins 37 and 40 have both been assigned to human chromosome 1. Thus the human chromosomes 1 and 13 each carry at least two different connexin genes. Their exact location on these chromosomes is not yet known. From our results subchromosomal assignments can be deduced for the human cx32 gene to Xq13-p11, the human cx37 gene as well as the human cx40 gene to 1pter-q12, and the human cx43 gene to 6q14-qter. The generation of the connexin multigene family from a hypothetical ancestral connexin gene is discussed.     

Molecular cloning of a human Vent-like homeobox gene

We have isolated a previously unknown human homeobox-containing cDNA, VENT-like homeobox-2 (VENTX2), using PCR with a bone marrow cDNA library and primers designed from the VENTX1 (alias HPX42) homeobox sequence. Here we describe the molecular cloning, chromosomal localization to 10q26.3, and functional analysis of this gene. The 2.4-kb human VENTX2 cDNA encoded a protein with a predicted molecular weight of 28 kDa containing a homeodomain with 65% identity to the Xenopus laevis ventralizing gene Xvent2B. VENTX2 antisera detected a 28-kDa protein in cells transfected with a VENTX2 expression construct, in a human erythroleukemic cell line and in bone marrow samples obtained from patients in recovery phase after chemotherapy. The similarity of the homeodomains from VENTX2 and the X. laevis Vent gene family places them in the same homeodomain class. Consistent with this structural classification, overexpression of VENTX2 in zebrafish embryos led to anterior truncations and failure to form a notochord, which are characteristics of ventralization.