Oleosin KD 18 on the surface of oil bodies in maize. Genomic and cDNA sequences and the deduced protein structure

Oleosins are newly discovered, abundant, and small Mr hydrophobic proteins localized on the surface of oil bodies in diverse seeds. So far, most of the studies have been on the general characteristics of the proteins, and only one protein (maize KD 16) has been studied using a cDNA clone containing an incomplete coding sequence. Here, we report the sequences of a genomic clone and a cDNA clone of a new maize oleosin (KD 18). There is no intron in the gene. The 5'-flanking region contains potential regulatory elements including RY repeats, CACA consensus, and CATC boxes, which are presumably involved in the specific expression of the proteins in maturing seeds. The deduced amino acid sequence was analyzed for secondary structures. We suggest that KD 18 of 187-amino acid residues contains three major structural domains: a largely hydrophilic domain at the N terminus, a hydrophobic hairpin alpha-helical domain at the center, and an amphipathic alpha-helix domain at the C terminus. These structural domains are very similar to those of oleosin KD 16. However, the KD 18 and KD 16 amino acid sequences as well as nucleotide sequences are highly similar only at the central domain (72 and 71%, respectively). The similarities are highest at the loop region of the alpha-helical hairpin. These results suggest that KD 18 and KD 16 are isoforms, encoded by genes derived from a common ancestor gene. We propose that the hairpin domain acts as an indispensible internal signal for intracellular trafficking of oleosins during protein synthesis as well as an anchor for oleosins on the oil bodies. The other two domains can undergo relatively massive amino acid substitutions without impairing the structure/function of the oleosins or have evolved to generate oleosins having different functions.     

动物肌动蛋白基因中内含子的来源及存在意义的探讨

对动物界演化过程中肌动蛋白家族内含子插入位置分布的演化规律作了分析,并对相同插入位置的内含子序列按同亚型和不同亚型作了比较。结果得出:从整个肌动蛋白家族的外显子序列高度保守性推断整个肌动蛋白家族可能是从共同的祖先蛋白进化而来的;从同亚型肌动蛋白内含子序列的类似性随进化距离而变化,但在短进化距离的物种间,类似性都较高,不同亚型肌动蛋白内含子序列的类似性都较低,即使是同一物种(如人),类似性也远低于同亚型但进化距离较近的物种,由此可推断,同亚型肌动蛋白的内含子序列可能从共同祖先进化,不同亚型肌动蛋白的内含子序列从不同祖先进化,综上推断可导出内含子可能是在蛋白异化过程中获得的:还发现内含子在肌动蛋白家族编码基因中位置的分布随进化方向不同而逐步形成两种截然不同的模式,由此提出了内含子的位置分布与动物演化方向之间可能具有某种必然联系,为内含子的存在提出了某种依据。     

Evolution of homologous domains of cytoplasmic intermediate filament proteins and lamins

The earliest gene duplications in the evolution of the intermediate filament proteins created the ancestors of acidic keratins, basic keratins, nonepithelial intermediate filament proteins, and lamins. Biochemistry and function of cytoplasmic intermediate filaments differ greatly from those of lamins. Cytoplasmic intermediate filament proteins have a different cellular location than lamins, form different types of supramolecular structures, and are missing a protein segment found in lamins; but the data presented here indicate that the cytoplasmic intermediate filaments do not have a common ancestor separate from the ancestor of lamins. In the non-epithelial intermediate filament branch, the ancestor of neurofilament proteins and the common ancestor of desmin, vimentin, and glial fibrillary acidic protein (GFAP) diverged first. By evolutionary criteria, the intermediate filament protein recently discovered in neuronal cells does not belong to the neurofilament family but is more closely related to desmin, vimentin, and GFAP. Sequences of different sub-domains yield different evolutionary trees, possibly indicating existence of sub- domain-specific functions.      

Molecular phylogenetics of DNA 5mC-methyltransferases.

We have identified a total of 88 members of the DNA-(cytosine-5) methyltransferase (5mC MTase) family whose sequences have been deposited in the databases. The results of a comparison of these sequences is presented in the form of an alignment-based phylogenetic tree and sequence logos for 10 conserved motifs. Phylogenetic analysis showed that members of the family aggregate into subfamilies which are usually consistent with their target specificity. However, it was also shown that similar target specificity does not necessarily imply close homology of the catalytic domain of MTases, which strongly supports the hypothesis that target recognition evolved independently of catalytic properties. This analysis also indicate that the 5mC MTase was present in the cenancestor (last common ancestor) of eubacteria, archaebacteria, and eukaryotes. The phylogeny of the 5mC MTases catalytic domain provides the basis for establishing the patterns of evolutionary change that characterize this family of proteins with conserved structural core and variable and mobile modules not directly involved in formation of the active site.     

Gene structure of nuclear lamin LIII of Xenopus laevis; a model for the evolution of IF proteins from a lamin-like ancestor.

The lamin LIII gene of Xenopus laevis has been characterized. The gene is duplicated in the Xenopus genome. The transcribed region spreads over 22 kb of genomic DNA encoding 12 exons. Two alternatively spliced mRNAs are observed which encode LIII isoforms that differ only by the 12 C-terminal amino acids which, however, both contain the CaaX motif known to be the target of post-translational modifications. The intron pattern of the lamin LIII gene is strikingly similar to that of an invertebrate intermediate filament (IF) gene over the entire protein coding sequence. The similarity in gene structure is restricted to the rod domain when compared with vertebrate types I-III IF genes. Our data suggest a model of how IF proteins evolved from a lamin-like ancestor by deletion of two signal sequences; the nuclear localization signal and the C-terminal ras-related CaaX motif. The data rule out the previously proposed hypothesis that IF proteins evolved from an intronless ancestor with an early divergence of neuronal and non-neuronal IF proteins. Together with the data presented in the accompanying paper by Dodemond et al. it can be concluded that the tail domains of lamins and invertebrate IF proteins, but not those of vertebrate IF proteins, are homologous. Thus, the different vertebrate IF proteins probably evolved by combination of the central rod domain with different tail domains by exon shuffling.     

Intermediate filaments: a historical perspective

Intracellular protein filaments intermediate in size between actin microfilaments and microtubules are composed of a surprising variety of tissue specific proteins commonly interconnected with other filamentous systems for mechanical stability and decorated by a variety of proteins that provide specialized functions. The sequence conservation of the coiled-coil, alpha-helical structure responsible for polymerization into individual 10 nm filaments defines the classification of intermediate filament proteins into a large gene family. Individual filaments further assemble into bundles and branched cytoskeletons visible in the light microscope. However, it is the diversity of the variable terminal domains that likely contributes most to different functions. The search for the functions of intermediate filament proteins has led to discoveries of roles in diseases of the skin, heart, muscle, liver, brain, adipose tissues and even premature aging. The diversity of uses of intermediate filaments as structural elements and scaffolds for organizing the distribution of decorating molecules contrasts with other cytoskeletal elements. This review is an attempt to provide some recollection of how such a diverse field emerged and changed over about 30 years.     

Gene duplication in the evolution of the two complementing domains of gram-negative bacterial tetracycline efflux proteins

The resistance of Gram- bacteria to the broad-spectrum antibiotic tetracycline (Tc) results from energy-dependent drug efflux mediated by the tet gene product, the cytoplasmic membrane Tet protein. Amino acid (aa) sequences deduced from total tet nucleotide sequences of three different resistance determinants (classes A, B and C) indicate that the protein products [Tet(A), Tet(B), and Tet(C)] share a common ancestor. Hydropathic analysis of Tet sequences predicts twelve transmembrane segments in each protein, with six occurring in each half of the molecule. More importantly, the linear distributions of these segments in the N- and C-terminal halves are nearly identical, suggesting that the two halves of each Tet protein are related by a process of tandem gene duplication and divergence. Indeed, a variable but significant conservation of sequence was detected among the N- and C-terminal halves for all possible comparisons of the three proteins. Such conservation was not observed within other prokaryotic integral membrane proteins or when other prokaryotic proteins were compared to Tet halves. Similarity, both in sequence and in predicted transmembrane structural organization, strongly suggests that a common ancestor of Tet(A), Tet(B), and Tet(C) arose by duplication of a gene reading frame specifying a transmembrane protein of approximately 200 aa residues. The two halves of Tet proteins correspond to the two domains, alpha and beta, which have distinct, complementary roles in Tc efflux. Nevertheless, selective constraints to function in the cytoplasmic membrane have apparently led to maintenance of similar patterns of secondary structural organization in these complementary domains.     

Comparative structural analysis of desmoplakin, bullous pemphigoid antigen and plectin: members of a new gene family involved in organization of intermediate filaments.

Desmoplakins (DP) and bullous pemphigoid antigen (BPA) are major plaque components of the desmosome and hemidesmosome, respectively. These cell adhesion structures are both associated intimately with the intermediate filament (IF) network. Structural analyses of DP and BPA sequences have indicated that these molecules are likely to form extended dumbbell-shaped dimers with a central rod and globular end domains. Recent sequence data have indicated that the N-terminal domains of both DP and BPA (like their C-terminal domains) are highly related: the former contain regions of heptad repeats that are predicted to form several alpha-helical bundles. Comparisons of DP and BPA protein sequences with that of plectin (PL), a 466 kDa IF-associated protein, have also revealed large scale homology. Identities between their N-terminal domains are: DP:BPA = 35%, DP:PL = 32%, BPA:PL = 40%, suggesting that BPA is more closely related to PL than DP in this region. In the C-terminal domains, which contain a 38-residue repeating motif, however, DP and PL are closer relatives (identities: DP:BPA = 38%, BPA:PL = 40%, DP:PL = 49%). The central domains of all three proteins have extensive heptad repeat substructure, express the same periodic distribution of charged residues, and are predicted to form two-stranded alpha-helical coiled-coil ropes. These observations suggest that DP, BPA and PL belong to a new gene family encoding proteins involved in IF organization.     

The origins of modern proteomes

Distributions of phylogenetically related protein domains (fold superfamilies), or FSFs, among the three Superkingdoms (trichotomy) are assessed. Very nearly 900 of the 1200 FSFs of the trichotomy are shared by two or three Superkingdoms. Parsimony analysis of FSF distributions suggests that the FSF complement of the last common ancestor to the trichotomy was more like that of modern eukaryotes than that of archaea and bacteria. Studies of length distributions among members of orthologous families of proteins present in all three Superkingdoms reveal that such lengths are significantly longer among eukaryotes than among bacteria and archaea. The data also reveal that proteins lengths of eukaryotes are more broadly distributed than they are within archaeal and bacterial members of the same orthologous families. Accordingly, selective pressure for a minimal size is significantly greater for orthologous protein lengths in archaea and bacteria than in eukaryotes. Alignments of orthologous proteins of archaea, bacteria and eukaryotes are characterized by greater sequence variation at their N-terminal and C-terminal domains, than in their central cores. Length variations tend to be localized in the terminal sequences; the conserved sequences of orthologous families are localized in a central core. These data are consistent with the interpretation that the genomes of the last common ancestor (LUCA) encoded a cohort of FSFs not very different from that of modern eukaryotes. Divergence of bacterial and archaeal genomes from that common ancestor may have been accompanied by more intensive reductive evolution of proteomes than that expressed in eukaryotes. Dollo's Law suggests that the evolution of novel FSFs is a very slow process, while laboratory experiments suggests that novel protein genesis from preexisting FSFs can be relatively rapid. Reassortment of FSFs to create novel proteins may have been mediated by genetic recombination before the advent of more efficient splicing mechanisms.     

Several nodulins of soybean share structural domains but differ in their subcellular locations.

Four soybean cDNA nodule-specific clones encoding nodulin-23, -26b, -27 and -44 were observed to cross-hybridize under low stringency conditions. Nucleotide sequence analysis revealed that the cDNAs contain three distinct domains: two domains with 70 to 95% homology separated by a third domain unique to each cDNA. Despite a number of nucleotide insertions and deletions, the protein sequences are conserved in the two domains which correlate with the homologous nucleotide domains. The amino terminal domain of each nodulin contains putative signal sequences for membrane translocation, although only two (nodulin-23 and -44) meet all the criteria for a functional signal. Immuno-precipitation of hybrid-release translation products of the four cDNAs revealed that nodulin-23 is associated with the peribacteroid membrane while nodulin-27 is in the cytoplasmic fraction of the nodule. These four nodulins are members of a diverse family with conserved structural features and the genes encoding them appear to have recently evolved from a common ancestor.     

Structural comparison of cupredoxin domains: domain recycling to construct proteins with novel functions.

The three-dimensional structures of the copper-containing enzymes ascorbate oxidase, ceruloplasmin, and nitrite reductase, comprised of multiple domains with a cupredoxin fold, are consistent with having evolved from a common ancestor. The presence or absence of copper sites has complicated ascertaining the structural and evolutionary relationship among these and related proteins. Simultaneous structural superposition of the enzyme domains and their known cupredoxin relatives shows clearly that there are at least six cupredoxin classes, and that the evolution of the conserved core of these domains is independent of the presence or absence of copper sites. Relationships among the variable loops in these structures show that the two-domain ancestor of the blue oxidases contained a trinuclear-copper interface but could not have functioned in a monomeric state. Comparison of the sequence of the copper-containing, iron-regulating protein. Ferrous transport (Fet3) from yeast to the structurally defined core and loop residues of the cupredoxins suggests specific residues that could be involved in the ferroxidase activity of Fet3.     

Cloning and characterization of novel ficolins from the solitary ascidian, Halocynthia roretzi

Ficolins are animal lectins with collagen-like and fibrinogen-like domains. They are involved in the first line of host defense against pathogens. Human ficolin/P35 as well as mannose-binding lectin (MBL) activates the complement lectin pathway in association with MBL-associated serine proteases. To elucidate the origin and evolution of ficolins, we separated approximately 40 kDa (p40) and approximately 50 kDa (p50) N-acetylglucosamine-binding lectins from hemolymph plasma of the solitary ascidian. Binding assays revealed that p40 recognizes N-acetyl groups in association with a pyranose ring and that p50 recognizes N-acetylglucosamine alone. Based on the amino acid sequences of the proteins, we isolated two clones each of p40 and p50 from the ascidian hepatopancreas cDNA and determined the entire coding sequences of these clones. Because all of the clones contained both collagen-like and fibrinogen-like domains, we concluded that these were homologs of the mammalian ficolin family and designated ascidian ficolins (AsFCNs). The fibrinogen-like domain of the AsFCNs shows 45.4-52.4% amino acid sequence identity with the mammalian ficolin family. A phylogenetic tree of the fibrinogen-like sequences shows that all the fibrinogen-like domains may have evolved from a common ancestor that branched off an authentic fibrinogen. These results suggest that AsFCNs play an important role with respect to ascidian hemolymph lectin activity and the correlation of different functions with binding specificity.     

Crystal structure of the calcium-loaded spherulin 3a dimer sheds light on the evolution of the eye lens betagamma-crystallin domain fold

BACKGROUND: The betagamma-crystallins belong to a superfamily of two-domain proteins found in vertebrate eye lenses, with distant relatives occurring in microorganisms. It has been considered that an eukaryotic stress protein, spherulin 3a, from the slime mold Physarum polycephalum shares a common one-domain ancestor with crystallins, similar to the one-domain 3-D structure determined by NMR. RESULTS: The X-ray structure of spherulin 3a shows it to be a tight homodimer, which is consistent with ultracentrifugation studies. The (two-motif) domain fold contains a pair of calcium binding sites very similar to those found in a two-domain prokaryotic betagamma-crystallin fold family member, Protein S. Domain pairing in the spherulin 3a dimer is two-fold symmetric, but quite different in character from the pseudo-two-fold pairing of domains in betagamma-crystallins. There is no evidence that the spherulin 3a single domain can fold independently of its partner domain, a feature that may be related to the absence of a tyrosine corner. CONCLUSION: Although it is accepted that the vertebrate two-domain betagamma-crystallins evolved from a common one-domain ancestor, the mycetezoan single-domain spherulin 3a, with its unique mode of domain pairing, is likely to be an evolutionary offshoot, perhaps from as far back as the one-motif ancestral stage. The spherulin 3a protomer stability appears to be dependent on domain pairing. Spherulin-like domain sequences that are found within bacterial proteins associated with virulence are likely to bind calcium.     

Molecular evolution and secondary structural conservation in the B-cell lymphoma leukemia 2 (bcl-2) family of proto-oncogene products

The nature of the bcl-2 family of protooncogenes was analyzed by sequence alignment, secondary structure prediction, and phylogenetic techniques. Phylogenies were inferred from both the nucleic acid and amino acid sequences of the human, murine, rat, and chicken sequences for BCL-2 and BCL-X, human MCL1, murine A1, the nematode Caenorhabditis elegans and Caenorhabditis briggsiae ced-9 proteins, and the sequences BHRF1 from Epstein-Barr and LMW5-HL from African swine fever viruses. Both sequence alignment and secondary structure prediction techniques supported the conservation of both the overall secondary structure and the carboxy-terminal transmembrane domain in all members of the family. All the treeing methods employed (distance matrix, maximum likelihood, and parsimony) supported a tree in which the proapoptotic proteins BCL-2 and BCL-X represent the most recent additions to the group. All the trees also indicated that the viral proteins BHRF1 and LMW-HL arose from a common ancestor, an ancestor they shared in common with the pro-apoptotic control protein BAX, indicating that this function of BAX evolved only recently. The most ancient branches are represented by the nematode ced-9 protein and by the control genes MCL1 and A1, which in the treeing methods employed represent separate lineages within the most ancient grouping. These results demonstrate the evolution of a highly conserved family of developmental control genes from nematode to man—genes that encode proteins essential for normal development but which are highly conserved in terms of predicted structure and possible cellular localization. The evolutionary analysis also indicates that the family may be even larger than originally predicted and that other members are waiting to be discovered. Correspondence to: D. Lloyd Evans     

The mammalian PYHIN gene family: Phylogeny, evolution and expression

ABSTRACT: BACKGROUND: Proteins of the mammalian PYHIN (IFI200/HIN-200) family are involved in defence against infection through recognition of foreign DNA. The family member absent in melanoma 2 (AIM2) binds cytosolic DNA via its HIN domain and initiates inflammasome formation via its pyrin domain. AIM2 lies within a cluster of related genes, many of which are uncharacterised in mouse. To better understand the evolution, orthology and function of these genes, we have documented the range of PYHIN genes present in representative mammalian species, and undertaken phylogenetic and expression analyses. RESULTS: No PYHIN genes are evident in non-mammals or monotremes, with a single member found in each of three marsupial genomes. Placental mammals show variable family expansions, from one gene in cow to four in human and 14 in mouse. A single HIN domain appears to have evolved in the common ancestor of marsupials and placental mammals, and duplicated to give rise to three distinct forms (HIN-A, -B and -C) in the placental mammal ancestor. Phylogenetic analyses showed that AIM2 HIN-C and pyrin domains clearly diverge from the rest of the family, and it is the only PYHIN protein with orthology across many species. Interestingly, although AIM2 is important in defence against some bacteria and viruses in mice, AIM2 is a pseudogene in cow, sheep, llama, dolphin, dog and elephant. The other 13 mouse genes have arisen by duplication and rearrangement within the lineage, which has allowed some diversification in expression patterns. CONCLUSIONS: The role of AIM2 in forming the inflammasome is relatively well understood, but molecular interactions of other PYHIN proteins involved in defence against foreign DNA remain to be defined. The non-AIM2 PYHIN protein sequences are very distinct from AIM2, suggesting they vary in effector mechanism in response to foreign DNA, and may bind different DNA structures. The PYHIN family has highly varied gene composition between mammalian species due to lineage-specific duplication and loss, which probably indicates different adaptations for fighting infectious disease. Non-genomic DNA can indicate infection, or a mutagenic threat. We hypothesise that defence of the genome against endogenous retroelements has been an additional evolutionary driver for PYHIN proteins.     

Membrane heredity and early chloroplast evolution

Membrane heredity was central to the unique symbiogenetic origin from cyanobacteria of chloroplasts in the ancestor of Plantae (green plants, red algae, glaucophytes) and to subsequent lateral transfers of plastids to form even more complex photosynthetic chimeras. Each symbiogenesis integrated disparate genomes and several radically different genetic membranes into a more complex cell. The common ancestor of Plantae evolved transit machinery for plastid protein import. In later secondary symbiogeneses, signal sequences were added to target proteins across host perialgal membranes: independently into green algal plastids (euglenoids, chlorarachneans) and red algal plastids (alveolates, chromists). Conservatism and innovation during early plastid diversification are discussed.     

A study of the evolution of inverted-topology repeats from LeuT-fold transporters using AlignMe

X-ray crystal structures have revealed that numerous secondary transporter proteins originally categorized into different sequence families share similar structures, namely, the LeuT fold. The core of this fold consists of two units of five transmembrane helices, whose conformations have been proposed to exchange to form the two alternate states required for transport. That these two units are related implies that LeuT-like transporters evolved from gene-duplication and fusion events. Thus, the origins of this structural repeat may be relevant to the evolution of transport function. However, the lack of significant sequence similarity requires sensitive sequence search methods for analyzing their evolution. To this end, we developed a software application called AlignMe, which can use various types of input information, such as residue hydrophobicity, to perform pairwise alignments of sequences and/or of hydropathy profiles of (membrane) proteins. We used AlignMe to analyze the evolutionary relationships between repeats of the LeuT fold. In addition, we identified proteins from the so-called DedA family that potentially share a common ancestor with these repeats. DedA domains have been implicated in, e.g., selenite uptake; they are found widely distributed across all kingdoms of life; two or more DedA domains are typically found per genome, and some may adopt dual topologies. These results suggest that DedA proteins existed in ancient organisms and may function as dimers, as required for a would-be ancestor of the LeuT fold. In conclusion, we provide novel insights into the evolution of this important structural motif and thus potentially into the alternating-access mechanism of transport itself.     

Structural and functional analysis of the PDZ domains of human HtrA1 and HtrA3

High-temperature requirement A (HtrA) and its homologs contain a serine protease domain followed by one or two PDZ domains. Bacterial HtrA proteins and the mitochondrial protein HtrA2/Omi maintain cell function by acting as both molecular chaperones and proteases to manage misfolded proteins. The biological roles of the mammalian family members HtrA1 and HtrA3 are less clear. We report a detailed structural and functional analysis of the PDZ domains of human HtrA1 and HtrA3 using peptide libraries and affinity assays to define specificity, structural studies to view the molecular details of ligand recognition, and alanine scanning mutagenesis to investigate the energetic contributions of individual residues to ligand binding. In common with HtrA2/Omi, we show that the PDZ domains of HtrA1 and HtrA3 recognize hydrophobic polypeptides, and while C-terminal sequences are preferred, internal sequences are also recognized. However, the details of the interactions differ, as different domains rely on interactions with different residues within the ligand to achieve high affinity binding. The results suggest that mammalian HtrA PDZ domains interact with a broad range of hydrophobic binding partners. This promiscuous specificity resembles that of bacterial HtrA family members and suggests a similar function for recognizing misfolded polypeptides with exposed hydrophobic sequences. Our results support a common activation mechanism for the HtrA family, whereby hydrophobic peptides bind to the PDZ domain and induce conformational changes that activate the protease. Such a mechanism is well suited to proteases evolved for the recognition and degradation of misfolded proteins.