Nageiaceae—A New Gymnosperm Family

A new monotypic gymnosperm family, Nageiaceae D. Z. Fu, is separated from Podocarpaceae. It is characterized by having multinerved leaves without costae, and primitive shoot-like female reproductive organs (female strobili). The new family contains a single genus consisting of 2 sections, 5 species and is distributed along the western coast of the Pacific, from low coastal mountains of eastern and southern Asia to the Phillipines and Papua New Guinea. The first species in the Nageiaceae was described as an angiosperm, Myrica nagi Thunb. (1784), but it was soon recognized to be a gymnosperm belonging to a new genus, and was renamed as Nageia japonica Gaert. (1788). The generic name, Nageia, however, has seldom been used, and the members of Nageia have generally been treated as an isolated section of Podocarpus in the Podocarpaceae. When revising the Podocarpaceae, De Laubenfels (1969) established a new genus Decussocarpus based on Nageia, but several years later (1987) he revived the old generic name, Nageia. Page ( 1988,1990)considered Nageia to be a valid generic name and redefined it as a natural genus. The distinctive,broadly lanceolate, multinerved leaves (without costae) of Nageia are rather unusual in gymnosperms,only being similar to those of Agathis in the Araucariaceae, their leaves are also similar to each other in anatomy. For example, there are many single vascular bundles arranged parallelly, between which occur sclerenchyma cells in the mesophyll. Apparently,leaves in Nageia are rather similar both externally and internally to paleogymnosperm cordaitean leaves, and sclerenchyma cells found in Nageia might be the remains of straps between veins in cordaitean leaves. In addition to leaf characters, the large and nearly round pith of the young shoot in Nageia appears to be a reminiscent of the large pith in cordaitean stem. The female reproductive organs (female strobili ) in Nageia are shoot-like. The female strobilus has a sterile terminal bud, and several opposite or subopposite sterile scaly bracts on its axis; two opposite megasporophylls are found near the axis apex and both have an anatropous ovule which is almost entirely covered by the megasporophyll; a bract is partly adnate to the lower back of the megasporophyll;mature arillate seeds are 1-2 or occasionally 3 in number; the axis becomes woody when the seeds mature, but in some species (N. wallichiana) the upper part of the axis becomes fleshy (in the shape of a receptacle), in which no distinct boundary was found between the fleshy receptacle and the woody part, and both have the same scaly bracts or traces. Many characters in Nageia are distinctly different from those in Podocarpus. Leaves in the Podocarpaceae have distinct midribs; in Podocarpus, the reproductive organ, which was generally thought to be similar to that in Nageia, has no terminal bud, and its bract is entirely free from the lower back of the megasporophyll, the fleshy receptacle is derived from both the axis and the sterile bracts (except the lowest two), and the female strobilus at the seed stage has a secondary stalk. The multinerved leaf in Nageia can rarely be found in most of the living gymnosperms except in some rather isolated groups, such as Araucariaceae, Ephedraceae,Ginkgoaceae and Welwitschiaceae. Paleobotanical evidence shows that multinerved leaves have been found in all of the geological ages from the Paleozoic to the present, and such a shoot-like female reproductive organ as in Nageia was found in some paleogymnosperms. It is very difficult to determine the systematic positions of these fossil plants because of lacks adequate material of reproductive organs or even lack of complete vegetative organs. The vascular system and leaf characters of gymnosperms are considered to be very conservative, and the fact that the common leaf shape and venation exist in both fossil and living gymnosperms could imply that there exists a multinerved-leaved evolutionary line ( M-line ) in gymnosperms, which could be traced back to the paleogymnosperm cordaitean plants or even older ones with multinerved leaves. The different types of the female strobili (female reproductive organs) of living gymnosperms, regardless of having one or only several seeds without a typical cone or many seeds with a cone, might have been derived from shoot-like or spikelike female reproductive organs possessed by their common ancestor.The fossil eviden ce shows that the typical cone similar to those of living gymnosperms first appeared in the Jurassic, much later than the single-seeded fossil plant without cones. The seed fossil appeared in the late Devonian Period. It is very difficult to infer the relationships among living gymnosperms, which are hardly derived from one another. But an analysis of the strobili, including the axis structure and position, number, morphology and degree of adnation of the phyllomes on them, would be helpful to the study of their phylogeny. It is evident, therefore, that the gymnosperms with leaves having a midrib might also have a rather long evolutionary course,but no transition between the midrib and multinerved patterns of leaf venation has so far been found in both living and fossil plants. Finally, it is noteworthy that the Nageiaceae are distributed along the western coast of the Pacific, where many primitive representatives, both in gymnosperms and angiosperms, still survive. This would be advantageous to the consideration of Nageiaceae as a primitive representative, or a descendant of fhe paleogymnos-perm cordaitean plants.     

Domain Evolution in the α-Amylase Family

The available amino acid sequences of the α-amylase family (glycosyl hydrolase family 13) were searched to identify their domain B, a distinct domain that protrudes from the regular catalytic (β/α)₈-barrel between the strand β3 and the helix α3. The isolated domain B sequences were inspected visually and also analyzed by Hydrophobic Cluster Analysis (HCA) to find common features. Sequence analyses and inspection of the few available three-dimensional structures suggest that the secondary structure of domain B varies with the enzyme specificity. Domain B in these different forms, however, may still have evolved from a common ancestor. The largest number of different specificities was found in the group with structural similarity to domain B from Bacillus cereus oligo-1,6-glucosidase that contains an α-helix succeeded by a three-stranded antiparallel β-sheet. These enzymes are α-glucosidase, cyclomaltodextrinase, dextran glucosidase, trehalose-6-phosphate hydrolase, neopullulanase, and a few α-amylases. Domain B of this type was observed also in some mammalian proteins involved in the transport of amino acids. These proteins show remarkable similarity with (β/α)₈-barrel elements throughout the entire sequence of enzymes from the oligo-1,6-glucosidase group. The transport proteins, in turn, resemble the animal 4F2 heavy-chain cell surface antigens, for which the sequences either lack domain B or contain only parts thereof. The similarities are compiled to indicate a possible route of domain evolution in the α-amylase family. Received: 4 December 1996 / Accepted: 13 March 1997     

Thank You from the Tuček Family

Note

Thank You from the Tuek Family     

Molecular Evolution of the Photolyase–Blue-Light Photoreceptor Family

The photolyase–blue-light photoreceptor family is composed of cyclobutane pyrimidine dimer (CPD) photolyases, (6-4) photolyases, and blue-light photoreceptors. CPD photolyase and (6-4) photolyase are involved in photoreactivation for CPD and (6-4) photoproducts, respectively. CPD photolyase is classified into two subclasses, class I and II, based on amino acid sequence similarity. Blue-light photoreceptors are essential light detectors for the early development of plants. The amino acid sequence of the receptor is similar to those of the photolyases, although the receptor does not show the activity of photoreactivation. To investigate the functional divergence of the family, the amino acid sequences of the proteins were aligned. The alignment suggested that the recognition mechanisms of the cofactors and the substrate of class I CPD photolyases (class I photolyases) are different from those of class II CPD photolyases (class II photolyases). We reconstructed the phylogenetic trees based on the alignment by the NJ method and the ML method. The phylogenetic analysis suggested that the ancestral gene of the family had encoded CPD photolyase and that the gene duplication of the ancestral proteins had occurred at least eight times before the divergence between eubacteria and eukaryotes. Received: 23 October 1996 / Accepted: 1 April 1997     

The Dicistroviridae： An Emerging Family of Invertebrate Viruses

Dicistroviruses comprise a newly characterized and rapidly expanding family of small RNA viruses of invertebrates. Several features of this virus group have attracted considerable research interest in recent years. In this review I provide an overview of the Dicistroviridae and describe progress made toward the understanding and practical application of dicistroviruses, including (i) construction of the first infectious clone of a dicistrovirus, (ii) use of the baculovirus expression system for production of an infectious dicistrovirus, (iii) the use of Drosophila C virus for analysis of host response to virus infection, and (iv) correlation of the presence of Israeli acute paralysis virus with honey bee colony collapse disorder. The potential use of dicistroviruses for insect pest management is also discussed. The structure, mechanism and practical use of the internal ribosome entry site (IRES) elements has recently been reviewed elsewhere.     

The α-Actinin Gene Family: A Revised Classification

The sequencing of a genome is the first stage of its complete characterization. Subsequent work seeks to utilize available sequence data to gain a better understanding of the genes which are found within a genome. Gene families comprise large portions of the genomes of higher vertebrates, and the available genomic data allow for a reappraisal of gene family evolution. This reappraisal will clarify relatedness within and between gene families. One such family, the alpha-actinin gene family, is part of the spectrin superfamily. There are four known loci, which encode alpha-actinins 1, 2, 3, and 4. Of the eight domains in alpha-actinin, the actin-binding domain is the most highly conserved. Here we present evidence gained through phylogenetic analyses of the highly conserved actin-binding domain that alpha-actinin 2 was the first of the four alpha-actinins to arise by gene duplication, followed by the divergence of alpha-actinin 3 and then alpha-actinins 1 and 4. Resolution of the gene tree for this gene family has allowed us to reclassify several alpha-actinins which were previously given names inconsistent with the most widely accepted nomenclature for this gene family. This reclassification clarifies previous discrepancies in the public databases as well as in the literature, thus eliminating confusion caused by continued misclassification of members of the alpha-actinin gene family. In addition, the topology found for this gene family undermines the 2R hypothesis theory of two rounds of genome duplication early in vertebrate evolution.     

A Fish-specific Member of the TPPP Protein Family?

A eukaryotic protein family, the tubulin polymerization promoting proteins (TPPPs), has recently been identified. It has been termed after its first member, TPPP/p25 or TPPP1, which exhibits microtubule-stabilizing function and plays a role in neurodegenerative diseases. In mammalian genomes, two further paralogues, TPPP2 and TPPP3, can be found. In this article, I show that TPPP1 and TPPP3, but not TPPP2, are included in paralogons, on human chromosomes, Hsa5 and Hsa16, respectively. I suggest that the single non-vertebrate tppp gene was duplicated in the first round of whole-genome duplication in the vertebrate lineage giving rise to tppp1 and the precursor of tppp2/tppp3. The existence of a teleost fish-specific fourth paralogue, tppp4, has also been raised, but it is not supported by synteny analysis. Alternatively, the new group can be considered as the fish orthologue of TPPP2. The case that the new group is the consequence of the teleost fish-specific whole-genome duplication (3R) cannot be excluded.     

The α-Actinin Gene Family: A Revised Classification

Abstract The sequencing of a genome is the first stage of its complete characterization. Subsequent work seeks to utilize available sequence data to gain a better understanding of the genes which are found within a genome. Gene families comprise large portions of the genomes of higher vertebrates, and the available genomic data allow for a reappraisal of gene family evolution. This reappraisal will clarify relatedness within and between gene families. One such family, the α-actinin gene family, is part of the spectrin superfamily. There are four known loci, which encode α-actinins 1, 2, 3, and 4. Of the eight domains in α-actinin, the actin-binding domain is the most highly conserved. Here we present evidence gained through phylogenetic analyses of the highly conserved actin-binding domain that α-actinin 2 was the first of the four α-actinins to arise by gene duplication, followed by the divergence of α-actinin 3 and then α-actinins 1 and 4. Resolution of the gene tree for this gene family has allowed us to reclassify several α-actinins which were previously given names inconsistent with the most widely accepted nomenclature for this gene family. This reclassification clarifies previous discrepancies in the public databases as well as in the literature, thus eliminating confusion caused by continued misclassification of members of the α-actinin gene family. In addition, the topology found for this gene family undermines the 2R hypothesis theory of two rounds of genome duplication early in vertebrate evolution.     

Phylogenetic Analysis of α-Galactosidases of the GH27 Family

Amino acid sequence analysis of -galactosidases and other proteins of glycoside hydrolase family 27 (GH27) allowed isolation of three major subfamilies, 27a–27c. Unique isomalto-dextranase of Arthrobacter globiformis clustered separately. Eukaryotic proteins formed five clusters on a phylogenetic tree of the family. Bacterial GH27 proteins, which are relatively few, did not form stable clusters. A monophyletic origin of the GH27 family was demonstrated with the use of related proteins of the GH36 family. The structure of the active center and evolution of -galactosidases are discussed.     

Family C1 cysteine proteases: biological diversity or redundancy?

Recent progress in the identification and partial characterization of novel genes encoding cysteine proteases of the papain family has considerably increased our knowledge of this family of enzymes. Kinetic data available to date for this large family indicate relatively broad, overlapping specificities for most enzymes, thus inspiring a growing conviction that they may exhibit functional redundancy. This is also supported in part by phenotypes of cathepsin knockout mice and suggests that several proteases can substitute for each other to degrade or process a given substrate. On the other hand, specific functions of one particular protease have also been documented. In addition, differences in cellular distribution and intracellular localization may contribute to defining specific functional roles for some of these proteases.     

Gene Conversion and Functional Divergence in the β-Globin Gene Family

Different models of gene family evolution have been proposed to explain the mechanism whereby gene copies created by gene duplications are maintained and diverge in function. Ohta proposed a model which predicts a burst of nonsynonymous substitutions following gene duplication and the preservation of duplicates through positive selection. An alternative model, the duplication–degeneration–complementation (DDC) model, does not explicitly require the action of positive Darwinian selection for the maintenance of duplicated gene copies, although purifying selection is assumed to continue to act on both copies. A potential outcome of the DDC model is heterogeneity in purifying selection among the gene copies, due to partitioning of subfunctions which complement each other. By using the d_N/d_S () rate ratio to measure selection pressure, we can distinguish between these two very different evolutionary scenarios. In this study we investigated these scenarios in the -globin family of genes, a textbook example of evolution by gene duplication. We assembled a comprehensive dataset of 72 vertebrate -globin sequences. The estimated phylogeny suggested multiple gene duplication and gene conversion events. By using different programs to detect recombination, we confirmed several cases of gene conversion and detected two new cases. We tested evolutionary scenarios derived from Ohtas model and the DDC model by examining selective pressures along lineages in a phylogeny of -globin genes in eutherian mammals. We did not find significant evidence for an increase in the ratio following major duplication events in this family. However, one exception to this pattern was the duplication of -globin in simian primates, after which a few sites were identified to be under positive selection. Overall, our results suggest that following gene duplications, paralogous copies of -globin genes evolved under a nonepisodic process of functional divergence.[Reviewing Editor: Martin Kreitman]     

Phylogenomic Analysis of the α Proteasome Gene Family from Early-Diverging Eukaryotes

We employed a phylogenomic approach to study the evolution of α subunits of the proteasome gene family from early diverging eukaryotes. BLAST similarity searches of the Giardia lamblia genome identified all seven α proteasome genes characteristic of eukaryotes from the crown group. In addition, a PCR strategy for the amplification of multiple α subunit sequences generated single α proteasome products for representatives of the Kinetoplastida (Leishmania major), the Parabasalia (Trichomonas vaginalis), and the Microsporidia (Vairimorpha sp., Nosema sp., Endoreticulata sp., and Spraguea lophii). The kinetoplastid Trypanosoma cruzi and the eukaryote crown group Acanthamoeba castellanii yielded two distinct α proteasome genes each. The presence of seven distinct α proteasome genes in G. lamblia, one of the earliest-diverging eukaryotes, indicates that the α proteasome gene family evolved rapidly from a minimum of one gene in Archaea to seven or more in Eukarya. Results from the phylogenomic analysis are consistent with the idea that the Diplomonida (as represented by G. lamblia), the Kinetoplastida, the Parabasalia, and the Microsporidia diverged after the duplication events that originated the α proteasome gene family. A model for the early origin and evolution of the proteasome gene family is presented. Received: 14 February 2000 / Accepted: 14 August 2000     

Identification of Novel Peptidyl Serine α-Galactosyltransferase Gene Family in Plants

In plants, serine residues in extensin, a cell wall protein, are glycosylated with O-linked galactose. However, the enzyme that is involved in the galactosylation of serine had not yet been identified. To identify the peptidyl serine O-α-galactosyltransferase (SGT), we chose Chlamydomonas reinhardtii as a model. We established an assay system for SGT activity using C. reinhardtii and Arabidopsis thaliana cell extracts. SGT protein was partially purified from cell extracts of C. reinhardtii and analyzed by tandem mass spectrometry to determine its amino acid sequence. The sequence matched the open reading frame {"type":"entrez-protein","attrs":{"text":"XP_001696927","term_id":"159477661","term_text":"XP_001696927"}}XP_001696927 in the C. reinhardtii proteome database, and a corresponding DNA fragment encoding 748 amino acids ({"type":"entrez-protein","attrs":{"text":"BAL63043","term_id":"377652299","term_text":"BAL63043"}}BAL63043) was cloned from a C. reinhardtii cDNA library. The 748-amino acid protein (CrSGT1) was produced using a yeast expression system, and the SGT activity was examined. Hydroxylation of proline residues adjacent to a serine in acceptor peptides was required for SGT activity. Genes for proteins containing conserved domains were found in various plant genomes, including A. thaliana and Nicotiana tabacum. The AtSGT1 and NtSGT1 proteins also showed SGT activity when expressed in yeast. In addition, knock-out lines of AtSGT1 and knockdown lines of NtSGT1 showed no or reduced SGT activity. The SGT1 sequence, which contains a conserved DXD motif and a C-terminal membrane spanning region, is the first example of a glycosyltransferase with type I membrane protein topology, and it showed no homology with known glycosyltransferases, indicating that SGT1 belongs to a novel glycosyltransferase gene family existing only in the plant kingdom.     

Evolutionary History of Eukaryotic α-Glucosidases from the α-Amylase Family

Although some α-glucosidases from the α-amylase family (glycoside hydrolase family GH13) have been studied extensively, their exact number, organization on the chromosome, and orthology/paralogy relationship were unknown. This was true even for important disease vectors where gut α-glucosidase is known to be receptor for the Bin toxin used to control the population of some mosquito species. In some cases orthologs from related species were studied intensively, while potentially important paralogs were omitted. We have, therefore, used a bioinformatics approach to identify all family GH13 α-glucosidases from the selected species from Metazoa (including three mosquito species: Aedes aegypti, Anopheles gambiae, and Culex quinquefasciatus) as well as from Fungi in an effort to characterize their arrangement on the chromosome and evolutionary relationships among orthologs and among paralogs. We also searched for pseudogenes and genes coding for enzymatically inactive proteins with a possible new function. We have found GH13 α-glucosidases mostly in Arthropoda and Fungi where they form gene families, as a result of multiple lineage-specific gene duplications. In mosquito species we have identified 14 α-glucosidase (Aglu) genes of which only five have been biochemically characterized so far, two are putative pseudogenes and the rest remains uncharacterized. We also revealed quite a complex evolutionary history of the eukaryotic α-glucosidases probably involving multiple losses of genes or horizontal gene transfer from bacteria.