Kinesin-related genes from diplomonad,sponge, amphioxus,and cyclostomes: divergence pattern of kinesin family and evolution of giardial membrane-bounded organella

To understand the question of whether divergence of eukaryotic genes by gene duplications and domain shufflings proceeded gradually or intermittently during evolution, we have cloned and sequenced Giardia lamblia cDNAs encoding kinesins and kinesin-related proteins and have obtained 13 kinesin-related cDNAs, some of which are likely homologs of vertebrate kinesins involved in vesicle transfer to ER, Golgi, and plasma membrane. A phylogenetic tree of the kinesin family revealed that most gene duplications that gave rise to different kinesin subfamilies with distinct functions have been completed before the earliest divergence of extant eukaryotes. This suggests that the complex endomembrane system has arisen very early in eukaryotic evolution, and the diminutive ER and Golgi apparatus recognized in the giardial cells, together with the absence of mitochondria, might be characters acquired secondarily during the evolution of parasitism. To understand the divergence pattern of the kinesin family in the lineage leading to vertebrates, seven more Unc104-related cDNAs have been cloned from sponge, amphioxus, hagfish, and lamprey. The divergence pattern of the animal Unc104/KIF1 subfamily is characterized by two active periods in gene duplication interrupted by a considerably long period of silence, instead of proceeding gradually: animals underwent extensive gene duplications before the parazoan-eumetazoan split. In the early evolution of vertebrates around the cyclostome-gnathostome split, further gene duplications occurred, by which a variety of genes with similar structures over the entire regions were generated. This pattern of divergence is similar to those of animal genes involved in cell-cell communication and developmental control.     

Evolution of the family of intracellular lipid binding proteins in vertebrates

Members of the family of intracellular lipid binding proteins (iLBPs) have been implicated in cytoplasmic transport of lipophilic ligands, such as long-chain fatty acids and retinoids. iLBPs are low molecular mass proteins (14–16 kDa) sharing a common structural fold. The iLBP family likely arose through duplication and diversification of an ancestral iLBP gene. Phylogenetic analysis undertaken in the present study indicates that the ancestral iLBP gene arose after divergence of animals from fungi and plants. The first gene duplication was dated around 930 millions of years ago, and subsequent duplications in the succeeding 550 millions of years gave rise to the 16 iLBP types currently recognized in vertebrates. Four clusters of proteins, each binding a characteristic range of ligands, are evident from the phylogenetic tree. Evolution of different binding properties probably allowed cytoplasmic trafficking of distinct ligands. It is speculated that recruitment of an iLBP during evolution of animals enabled the mitochondrial oxidation of long-chain fatty acids.     

Characterization and evolution of napin-encoding genes in radish and related crucifers

Three cDNA clones, encoding napin storage proteins from radish, were isolated and sequenced. They fall into two classes differing in the size of the primary translation product. Sequences of the two classes are very well conserved and they display an organization very similar to that of the homologous genes from rapeseed and Arabidopsis which have previously been described. On the basis of hybridization intensity and the number of restriction fragments, we estimate that the radish napin multigene family is represented by eight to twelve members. The use of probes specific to each subfamily demonstrates that they contribute to a similar extent to the production of napin mRNA. Analysis of the sequence data suggests that the napin ancestral genes are probably derived from successive duplication and divergence of a protogene. Comparing other available napin sequences with those of radish reveals intriguing features. Comparison of the coding sequences shows that the homology between the radish and rapeseed sequences is much higher than that between each of the four members of the Arabidopsis gene family. This would suggest that the duplications which gave rise to the different members occurred independently in the two groups of species after separation of Arabidopsis from the Brassica lineage. However, similar comparison carried out on the 3' -noncoding sequences does not support this hypothesis, but shows that slightly different duplicated genes probably already existed in the common ancestor to the three genera. This paradox can be resolved by assuming that, within each genus, coding sequences for napin-encoding genes have been considerably homogenized as a result of concerted evolution.     

The organization of the keratin I and II gene clusters in placental mammals and marsupials show a striking similarity

The genomic database for a marsupial, the opossum Monodelphis domestica, is highly advanced. This allowed a complete analysis of the keratin I and keratin II gene cluster with some 30 genes in each cluster as well as a comparison with the human keratin clusters. Human and marsupial keratin gene clusters have an astonishingly similar organization. As placental mammals and marsupials are sister groups a corresponding organization is also expected for the archetype mammal. Since hair is a mammalian acquisition the following features of the cluster refer to its origin. In both clusters hair keratin genes arose at an interior position. While we do not know from which epithelial keratin genes the first hair keratins type-I and -II genes evolved, subsequent gene duplications gave rise to a subdomain of the clusters with many neighboring hair keratin genes. A second subdomain accounts in both clusters for 4 neighboring genes encoding the keratins of the inner root sheath (irs) keratins. Finally the hair keratin gene subdomain in the type-I gene cluster is interrupted after the second gene by a region encoding numerous genes for the high/ultrahigh sulfur hair keratin-associated proteins (KAPs). We also propose a tentative synteny relation of opossum and human genes based on maximal sequence conservation of the encoded keratins. The keratin gene clusters of the opossum seem to lack pseudogenes and display a slightly increased number of genes. Opossum keratin genes are usually longer than their human counterparts and also show longer intergenic distances.     

Evidence of independent gene duplications during the evolution of archaeal and eukaryotic family B DNA polymerases

Eukaryotes and archaea both possess multiple genes coding for family B DNA polymerases. In animals and fungi, three family B DNA polymerases, alpha, delta, and epsilon, are responsible for replication of nuclear DNA. We used a PCR-based approach to amplify and sequence phylogenetically conserved regions of these three DNA polymerases from Giardia intestinalis and Trichomonas vaginalis, representatives of early-diverging eukaryotic lineages. Phylogenetic analysis of eukaryotic and archaeal paralogs suggests that the gene duplications that gave rise to the three replicative paralogs occurred before the divergence of the earliest eukaryotic lineages, and that all eukaryotes are likely to possess these paralogs. One eukaryotic paralog, epsilon, consistently branches within archaeal sequences to the exclusion of other eukaryotic paralogs, suggesting that an epsilon-like family B DNA polymerase was ancestral to both archaea and eukaryotes. Because crenarchaeote and euryarchaeote paralogs do not form monophyletic groups in phylogenetic analysis, it is possible that archaeal family B paralogs themselves evolved by a series of gene duplications independent of the gene duplications that gave rise to eukaryotic paralogs.      

The cephalochordate Branchiostoma genome contains 26 intermediate filament (IF) genes: Implications for evolution of chordate IF proteins

We analyzed the draft genome of the cephalochordate Branchiostoma floridae (B. floridae) for genes encoding intermediate filament (IF) proteins. From 26 identified IF genes 13 were not reported before. Four of the new IF genes belong to the previously established Branchiostoma IF group A, four to the Branchiostoma IF group B, one is homologous to the type II keratin E2 while the remaining four new IF sequences N1 to N4 could not be readily classified in any of the previously established Branchiostoma IF groups. All eleven identified A and B2-type IF genes are located on the same genomic scaffold and arose due to multiple cephalochordate-specific duplications. Another IF gene cluster, identified in the B. floridae genome, contains three keratins (E1, Y1, D1), two keratin-like IF genes (C2, X1), one new IF gene (N1) and one IF unrelated gene, but does not show any similarities to the well defined vertebrate type I or type II keratin gene clusters. In addition, some type III sequence features were documented in the new IF protein N2, which, however, seems to share a common ancestry with the Branchiostoma keratins D1 and two keratin-related genes C. Thus, a few type I and type II keratin genes existed in a common ancestor of cephalochordates and vertebrates, which after separation of these two lineages gave rise to the known complexities of the vertebrate cytoplasmic type I–IV IF proteins, as well as to the multiple keratin and related IF genes in cephalochordates, due to multiple gene duplications, deletions and sequence divergences.     

Evolution of cytochrome P-450 proteins [published erratum appears in Mol Biol Evol 1988 Mar;5(2):199]

Thirty-four cytochrome P-450 sequences from one bacterial and six vertebrate species have been aligned with the aid of a computer alignment algorithm. Phylogenetic trees were constructed using the unweighted-pair-group and neighbor-joining methods. The two trees differed at only a single branch point near the base of the tree. The cytochrome P-450 superfamily of proteins clustered into eight families and contained 16 gene-duplication events. The first gene duplication occurred approximately 1,360 Myr before the present (Mybp) and gave rise to cytochrome P-450s found in two different cellular organelles, the mitochondria and the endoplasmic reticulum. Both groups utilize cholesterol or its metabolites as substrates, implying that cholesterol existed greater than 1,360 Mybp. The fourth gene duplication (approximately 900 Mybp) gave rise to the drug-metabolizing P-450s. These proteins aid in the detoxification of foreign chemicals, as opposed to the metabolism of endogenous compounds. The importance of the capacity to metabolize drugs is reflected in 11 further gene duplications occurring in this lineage. The first occurred approximately 800 Mybp and gave rise to the two major P-450 families, the phenobarbital and 3-methylcholanthrene families. An apparent increase in the rate of cytochrome P-450 evolution is noted between the bird-mammal divergence (300 Mybp) and the mammalian radiation (75 Mybp).      

Sponge homologs of vertebrate protein tyrosine kinases and frequent domain shufflings in the early evolution of animals before the parazoan–eumetazoan split

The protein tyrosine kinases (PTKs) diverged specifically in animal lineages by gene duplications and domain shufflings to form a large protein family comprising diverse subfamilies with distinct domain organizations and functions. On the basis of a phylogenetic tree inferred from a comparison of the shared kinase domains, we previously showed that gene duplications that gave rise to diverse subfamilies predate the divergence of parazoans and eumetazoans. There is, however, still a possibility that, although the kinase domain duplications are ancient events, the domain shufflings that gave rise to different subfamilies with distinct domain organization are more recent event than the kinase domain duplications. To clarify this problem, we have determined the complete sequences of 15 sponge PTKs and have compared the domain organizations of these sponge PTKs and those of eumetazoans. For each of ten sponge PTKs out of 15 analyzed here, a possible eumetazoan (human and Drosophila) ortholog has been identified. The sponge and eumetazoan orthologs are virtually identical in domain organization and belong to the same subfamily in the PTK family tree for each of ten orthologous pairs, except for one subfamily in which a considerable deletions and/or insertions of domains are observed. This result suggests that most, if not all, of the domain shufflings, together with gene duplications, are very old, going back to dates before the parazoan–eumetazoan split, the earliest divergence among extant animal phyla.     

Comparative analysis of Phytophthora genes encoding secreted proteins reveals conserved synteny and lineage-specific gene duplications and deletions

Comparative analysis of two Phytophthora genomes revealed overall colinearity in four genomic regions consisting of a 1.5-Mb sequence of Phytophthora sojae and a 0.9-Mb sequence of P. ramorum. In these regions with conserved synteny, the gene order is largely similar; however, genome rearrangements also have occurred. Deletions and duplications often were found in association with genes encoding secreted proteins, including effectors that are important for interaction with host plants. Among secreted protein genes, different evolutionary patterns were found. Elicitin genes that code for a complex family of highly conserved Phytophthora-specific elicitors show conservation in gene number and order, and often are clustered. In contrast, the race-specific elicitor gene Avrlb-1 appeared to be missing from the region with conserved synteny, as were its five homologs that are scattered over the four genomic regions. Some gene families encoding secreted proteins were found to be expanded in one species compared with the other. This could be the result of either repeated gene duplications in one species or specific deletions in the other. These different evolutionary patterns may shed light on the functions of these secreted proteins in the biology and pathology of the two Phytophthora spp.     

Lactate dehydrogenase (LDH) gene duplication during chordate evolution: the cDNA sequence of the LDH of the tunicate Styela plicata

L-Lactate dehydrogenase (L-LDH, E.C. 1.1.1.27) is encoded by two or three loci in all vertebrates examined, with the exception of lampreys, which have a single LDH locus. Biochemical characterizations of LDH proteins have suggested that a gene duplication early in vertebrate evolution gave rise to Ldh-A and Ldh-B and that an additional locus, Ldh-C arose in a number of lineages more recently. Although some phylogenetic studies of LDH protein sequences have supported this pattern of gene duplication, others have contradicted it. In particular, a number of studies have suggested that Ldh-C represents the earliest divergence among vertebrate LDHs and that it may have diverged from the other loci well before the origin of vertebrates. Such hypotheses make explicit statements about the relationship of vertebrate and invertebrate LDHs, but to date, no closely related invertebrate LDH sequences have been available for comparison. We have attempted to provide further data on the timing of gene duplications leading to multiple vertebrate LDHs by determining the cDNA sequence of the LDH of the tunicate Styela plicata. Phylogenetic analyses of this and other LDH sequences provide strong support for the duplications giving rise to multiple vertebrate LDHs having occurred after vertebrates diverged from tunicates. The timing of these LDH duplications is consistent with data from a number of other gene families suggesting widespread gene duplication near the origin of vertebrates. With respect to the relationships among vertebrate LDHs, our data are not consistent with previous claims that Ldh-C represented the earliest divergence. However, the precise relationships among some of the main lineages of vertebrate LDHs were not resolved in our analyses.      

Evolution of the Relaxin/Insulin-like Gene Family in Placental Mammals: Implications for Its Early Evolution

The relaxin (RLN) and insulin-like (INSL) gene family is a group of genes involved in a variety of physiological roles that includes bone formation, testicular descent, trophoblast development, and cell differentiation. This family appears to have expanded in vertebrates relative to non-vertebrate chordates, but the relative contribution of whole genome duplications (WGDs) and tandem duplications to the observed diversity of genes is still an open question. Results from our comparative analyses favor a model of divergence post vertebrate WGDs in which a single-copy progenitor found in the last common ancestor of vertebrates experienced two rounds of WGDs before the functional differentiation that gave rise to the RLN and INSL genes. One of the resulting paralogs was subsequently lost, resulting in three proto-RLN/INSL genes on three separate chromosomes. Subsequent rounds of tandem gene duplication and divergence originated the set of paralogs found on a given cluster in extant vertebrates. Our study supports the hypothesis that differentiation of the RLN and INSL genes took place independently in each RLN/INSL cluster after the two WGDs during the evolutionary history of vertebrates. In addition, we show that INSL4 represents a relatively old gene that has been apparently lost independently in all Euarchontoglires other than apes and Old World monkeys, and that RLN2 derives from an ape-specific duplication.     

Evolution of the lung surfactant proteins in birds and mammals

Phylogenetic analyses of the families of mammalian lung surfactant proteins (SP-A, SP-B, SP-C, and SP-D) supported the hypothesis that these proteins have diverged between birds and mammals as a result of lineage-specific gene duplications and deletions. Homologs of mammalian genes encoding SP-B, SP-C, and SP-D appear to have been deleted in chickens, whereas there was evidence of avian-specific duplications of the genes encoding SP-A and presaposin. Analysis of the genes closely linked to human SP-B, SP-C, and SP-D genes revealed that all three of these genes are closely linked to genes having orthologs on chicken chromosome 6 and also to genes lacking chicken orthologs. These relationships suggest that all of the lung surfactant protein genes, as well as certain related genes, may have been linked in the ancestor of humans and chickens. Further, they imply that the loss of surfactant protein genes in the avian lineages formed part of major genomic rearrangement events that involved the loss of other genes as well. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Species-specific size expansion and molecular evolution of the oleosins in angiosperms

Oleosins are hydrophobic plant proteins thought to be important for the formation of oil bodies, which supply energy for seed germination and subsequent seedling growth. To better understand the evolutionary history and diversity of the oleosin gene family in plants, especially angiosperms, we systematically investigated the molecular evolution of this family using eight representative angiosperm species. A total of 73 oleosin members were identified, with six members in each of four monocot species and a greater but variable number in the four eudicots. A phylogenetic analysis revealed that the angiosperm oleosin genes belonged to three monophyletic lineages. Species-specific gene duplications, caused mainly by segmental duplication, led to the great expansion of oleosin genes and occurred frequently in eudicots after the monocot–eudicot divergence. Functional divergence analyses indicate that significant amino acid site-specific selective constraints acted on the different clades of oleosins. Adaptive evolution analyses demonstrate that oleosin genes were subject to strong purifying selection after their species-specific duplications and that rapid evolution occurred with a high degree of evolutionary dynamics in the pollen-specific oleosin genes. In conclusion, this study serves as a foundation for genome-wide analyses of the oleosins. These findings provide insight into the function and evolution of this gene family in angiosperms and pave the way for studies in other plants.     

Duplex (or quadruplet) CH domain containing human multidomain proteins: an inventory

In this paper, the inventory presented for singlet CH (calponin homology/actin binding) domain containing human multidomain proteins [1] is extended to several duplex and one quadruplet CH containing forms. Invariably, the duplexes are located at the begin of the molecules. The regions connecting the two CH units suggest amino acid conservations which allows the placing of 18 duplex containing molecules into six groups wherein the gene for one member in each group created the others more recently by gene duplication. The ancient multidomain proteins, possibly, were primarily the result of an exon shuffling (transposition) mechanism that also guided the placing of the CH singlet or duplex domain at the amino end of the newly created proteins. A mechanism that creates pseudogenes could conceivably produce genes that encode multi-domain proteins. Intragenomic duplications (slippage) might have facilitated the occurrence of encoding repeats, thus allowing for the creation of multiple identical domains within one molecule. Gene duplication with subsequent modification and small domain gene recombination which formed multidomain proteins are important forces driving evolution.     

Nucleotide sequence, function, activation, and evolution of the cryptic asc operon of Escherichia coli K12.

The cryptic asc (previous called "SAC") operon of Escherichia coli K12 has been completely sequenced. It encodes a repressor (ascG); a PTS enzyme IIasc for the transport of arbutin, salicin, and cellobiose (ascF); and a phospho-beta-glucosidase that hydrolyzes the sugars which are phosphorylated during transport (ascB). ascG and ascFB are transcribed from divergent promoters. The cryptic operon is activated by the insertion of IS186 into the ascG (repressor) gene. The ascFB genes are paralogous to the cryptic bglFB genes, and ascG is paralogous to galR. The duplications that gave rise to these paralogous genes are estimated to have occurred approximately 320 Mya, a time that predates the divergence of E. coli and Salmonella typhimurium.     

Molecular characterization and expression analysis of nine cotton GhEF1A genes encoding translation elongation factor 1A

The translation elongation factor 1A, eEF1A, plays an important role in protein synthesis, catalyzing the binding of aminoacyl-tRNA to the A-site of the ribosome by a GTP-dependent mechanism. To investigate the role of eEF1A for protein synthesis in cotton fiber development, nine different cDNA clones encoding eukaryotic translation elongation factor 1A were isolated from cotton (Gossypium hirsutum) fiber cDNA libraries. The isolated genes (cDNAs) were designated cotton elongation factor 1A gene GhEF1A1, GhEF1A2, GhEF1A3, GhEF1A4, GhEF1A5, GhEF1A6, GhEF1A7, GhEF1A8, GhEF1A9, respectively. They share high sequence homology at nucleotide level (71-99% identity) in the coding region and at amino acid level (96-99% identity) among each other. Phylogenetic analysis demonstrated that the nine GhEF1A genes can be divided into 5-6 subfamilies, indicating the divergence occurred in structures of the genes as well as the deduced proteins during evolution. Real-time quantitative RT-PCR analysis revealed that GhEF1A genes are differentially expressed in different tissues/organs. Of the nine GhEF1A genes, five are expressed at relatively high levels in young fibers. Further analysis indicated that expressions of the GhEF1As in fiber are highly developmental-regulated, suggesting that protein biosynthesis is very active at the early fiber elongation.     

Lateral transfer of an EF-1alpha gene: origin and evolution of the large subunit of ATP sulfurylase in eubacteria

It is generally accepted that new genes arise via duplication and functional divergence of existing genes, in accordance with Ohno's model, now called "Mutation During Redundancy," or MDR. In this model, one of the two gene copies is free to acquire novel (although likely related) activities through mutation, since only one copy is required for its original function. However, duplication within a genome is not the only process that might give rise to this situation: acquisition of a functionally redundant gene by lateral gene transfer (LGT) could also initiate the MDR process. Here we describe a probable instance, involving LGT of an archaeal or eukaryotic elongation factor 1alpha (EF-1alpha) gene. The large subunit of ATP sulfurylase (CysN or the N-terminal portion of NodQ), found mainly in proteobacteria, is clearly related to translation elongation factors. However, our analyses show that cysN arose from an EF-1alpha gene initially acquired by LGT, not from a within-genome duplication of the resident EF-Tu gene. To our knowledge, this is the first unequivocal case of LGT followed by functional modification to be described; this mechanism could be a potentially important force in establishing genes with novel functions in genomes.     

Phylogenetic analysis of vertebrate and invertebrate Delta/Serrate/LAG-2 (DSL) proteins

Delta/Serrate/LAG-2 (DSL) proteins are putative transmembrane signaling molecules that regulate cell differentiation in metazoans. DSL proteins are characterized by the presence of a motif unique to these proteins, the DSL motif, and a variable number of tandemly repeated copies of an epidermal growth factor-like (EGF) motif. We have completed a phylogenetic analysis of 15 DSL proteins from eight species. Our findings reveal that at least one gene duplication occurred prior to the divergence of the Drosophila melanogaster and vertebrate lineages, with subsequent duplications in vertebrates. The three known Caenorhabditis elegans proteins likely arose by two independent duplications in the nematode lineage. Analysis of EGF repeats suggests that EGF 2 has been conserved among DSL proteins in vertebrates and D. melanogaster. The sequences of two EGF repeats have been perfectly conserved in vertebrate orthologs: EGF 2 in Delta and EGF 15 in Jagged/Serrate. Finally, the linear order of EGF repeats has been conserved in the vertebrate Jagged/Serrate orthologs and vertebrate Delta orthologs.