Evolutionary patterns of killer cell Ig-like receptor genes in Old World monkeys

Killer cell Ig-like receptors (KIRs) modulate the cytotoxic effects of Natural Killer cells. KIR genes are encoded in the Leucocyte Receptor Complex and are characterized by their high haplotypic diversity and polymorphism. The KIR system has been studied in only three species of Old World monkeys, the rhesus macaque, the cynomolgus macaque, and the sabaeus monkey, displaying a complexity rivaling that of hominids (human and apes). Here we analyzed bacterial artificial chromosome draft sequences spanning the KIR haplotype of three other Old World monkeys, the vervet monkey (Chlorocebus aethiops), the olive baboon (Papio anubis) and the colobus monkey (Colobus guereza). A total of 25 KIR gene models were identified in these species, predicted to encode receptors with 1, 2, and 3 extracellular Ig domains, all of them with long cytoplasmic domains having two putative ITIMs, although three had a positively charged residue in the transmembrane domain. Sequence and phylogenetic analyses showed that most Old World monkeys shared five classes of KIR loci: i) KIR2DL5/3DL20 in the most centromeric region, followed by ii) the single Ig domain-encoding locus KIR1D, iii) the pseudogene KIR2DP, iv) the conserved KIR2DL4, and v) the highly diversified KIR3DL/H loci in the telomeric half of the cluster. An exception to this pattern was the KIR haplotype of the colobus monkey that lacked the KIR1D, KIR2DP, and KIR2DL4 loci of the central region of the cluster. Thus, Old World monkeys display a broad spectrum of KIR haplotype variation that has been generated upon an ancestral haplotype architecture by gene duplication, gene deletion, and non-homologous recombination.     

Relative evolutionary rates of NBS-encoding genes revealed by soybean segmental duplication

It is well known that nucleotide binding site (NBS)-encoding genes are duplicate-rich and fast-evolving genes. However, there is little information on the relative importance of tandem and segmental NBS duplicates and their exact evolutionary rates. The two rounds of large-scale duplication that have occurred in soybean provide a unique opportunity to investigate these issues. Comparison of NBS and non-NBS genes on segments of syntenic homoeologs shows that NBS-encoding genes evolve at least 1.5-fold faster (~1.5-fold higher synonymous and approximately 2.3-fold higher nonsynonymous substitution rates) and lose their genes approximately twofold faster than the flanking non-NBS genes. Compared with segmental duplicates, tandem NBS duplicates are more abundant in soybean, suggesting that tandem duplication is the major driving force in the expansion of NBS genes. Notably, significant sequence exchanges along with significantly positive selection were detected in most tandem-duplicated NBS gene families. The results suggest that the rapid evolution of NBS genes may be due to the combined effects of diversifying selection and frequent sequence exchanges. Interestingly, TIR-NBS-LRR genes (TNLs) have a higher nucleotide substitution rate than non-TNLs, indicating that these types of NBS genes may have a rather different evolutionary pattern. It is important to determine the exact relative evolutionary rates of TNL, non-TNL, and non-NBS genes in order to understand how fast the host plant can adjust its response to rapidly evolving pathogens in a coevolutionary context.     

Sensitivity of cell division and cell elongation to low water potentials in soybean hypocotyls

Summary The response of cell division and cell elongation to low cell water potentials was studied in etiolated, intact soybean hypocotyls desiccated either by withholding water from seedlings or by subjecting hypocotyls to pressure. Measurements of hypocotyl water potential and osmotic potential indicated that desiccation by withholding water resulted in osmotic adjustment of the hypocotyls so that turgor remained almost constant. The adjustment appeared to involve transport of solutes from the cotyledons to the hypocotyl and permitted growth of the seedlings at water potentials which would have been strongly inhibitory had adjustment not occurred. Growth was ultimately inhibited in hypocotyls due to inhibition of cell division and cell elongation to a similar degree. The inhibition of cell elongation appeared to result from a change in the minimum turgor necessary for growth. On the other hand, when intact hypocotyls were exposed to pressure for 3 h, osmotic adjustment did not occur, turgor decreased, and the sensitivity of growth to low cell water potentials increased, presumably due to inhibition of cell elongation. Thus, although cell division was sensitive to low cell water potentials in soybean hypocotyls, cell elongation had either the same sensitivity or was more sensitive, depending on whether the tissue adjusted osmotically. Osmotic adjustment of hypocotyls may represent a mechanism for preserving growth in seedlings germinating in desiccated soil.Supported by a grant from the Illinois Agricultural Experiment Station, University of Illinois and grant 1-T1-GM-1380 from the United States Public Health Service.     

Evolutionary analysis of three gibberellin oxidase genes in rice, Arabidopsis, and soybean

GAs are plant hormones that play fundamental roles in plant growth and development. GA2ox, GA3ox, and GA20ox are three key enzymes in GA biosynthesis. These enzymes belong to the 2OG-Fe (II) oxygenase superfamily and are independently encoded by different gene families. To date, genome-wide comparative analyses of GA oxidases in plant species have not been thoroughly carried out. In the present work, 61 GA oxidase family genes from rice (Oryza sativa), Arabidopsis, and soybean (Glycine max) were identified and a full study of these genes including phylogenetic tree construction, gene structure, gene family expansion and analysis of functional motifs was performed. Based on phylogeny, most of the GA oxidases were divided into four subgroups that reflected functional classifications. Intron/intron average length of GA oxidase genes in rice analysis revealed that GA oxidase genes in rice experienced substantial evolutionary divergence. Segmental duplication events were mainly found in soybean genome. However, in rice and Arabidopsis, no single expansion pattern exhibited dominance, indicating that GA oxidase genes from these species might have been subjected to a more complex evolutionary mechanism. In addition, special functional motifs were discovered in GA20ox, GA3ox, and GA2ox, which suggested that different functional motifs are associated with differences in protein function. Taken together our results suggest that GA oxidase family genes have undergone divergent evolutionary routes, especially at the monocot-dicot split, with dynamic evolution occurring in Arabidopsis thaliana and soybean.     

Dominant and recessive genes involved in tumor cell invasion

The past year has been the discovery and further analysis of several genes and protein products that are critically involved in the generation of invasive and metastatic tumor cells. Like oncogenes and tumor suppressor genes, the genes responsible for invasive and metastatic phenotypes can function in a dominant or recessive fashion. In this review, particular emphasis will be given to the dominantly acting genes encoding the cell adhesion molecule CD44 and the motility factor scatter factor, and the recessively acting genes encoding the cell adhesion molecule E-cadherin and nm23.     

The cell division genes (ftsE and X) of Aeromonas hydrophila and their relationship with opsonophagocytosis

A transposon mutant from Aeromonas hydrophila AH-3 was obtained which was highly resistant to opsonophagocytosis. The mutation was identified in the ftsE gene and we characterised the operon ftsY, E and X from this bacterium. These genes, as in enteric bacteria, are neighbours to rpoH. The A. hydrophilia ftsE and X genes were fully able to complement Escherichia coli ftsE mutants, and also complement the opsonophagocytosis-resistant phenotype of the A. hydrophila mutant strain. This phenotype seems to be related to the filamentous phenotype at 37 degrees C exhibited by the A. hydrophila ftsE mutant.     

Rapid expansion of killer cell immunoglobulin-like receptor genes in primates and their coevolution with MHC Class I genes

The gene family of killer cell immunoglobulin-like receptors (KIRs) in primates provides the first line of defense against virus infection and tumor transformation. Interacting with MHC class I molecules, KIRs can regulate the cytotoxic activity of natural killer (NK) cells and distinguish the tumor and virus infected cells from normal body cells. Phylogenetic analysis and comparison of domain structures identified three major groups of KIR genes (group I, II, and III genes). These groups of KIR genes, generated by a series of gene duplications, have acquired different MHC-binding specificity. Inference of ancestral KIR sequences suggested that the functional divergence of group I genes from group II genes occurred by positive selection at the MHC-binding sites after duplication. Our evolutionary study has shown that group I genes diverged from group II genes about 17 million years ago (Mya) apparently after separation of hominoids from Old World (OW) monkeys. Around the same time, gene duplication generating the class I MHC-C locus appears to have occurred. These findings suggest that KIR and MHC class I genes have coevolved as an interacting system. The KIR gene family has experienced a rapid expansion in primate species. The rate of expansion of this gene family seems to be one of the highest among all hominoid gene families. The KIR gene family is also subject to birth-and-death evolution.     

Cotransformation frequencies of foreign genes in soybean cell cultures

Summary Through the use of electroporation and a soybean (Glycine max L.) protoplast system, we generated stably transformed cell lines expressing a number of foreign genes (neomycin phosphotransferase,-glucuronidase, chloramphenicol acetyl transferase, and phosphinothricin acetyl transferase). Selected and unselected marker genes were cointroduced either linked on a single plasmid or as separate plasmids. Calli expressing multiple genes were recovered, and Cotransformation frequencies were established for both cases. Our results show a 50% cotransformation frequency in the case of linked genes. In situations in which two genes are introduced on independent plasmids, cotransformation frequencies are 18%–27%. Similar rates of cotransformation were observed among various marker pairs.     

An essential function of sphingolipids in yeast cell division

Ceramides are bioactive lipids and precursors to sphingolipids. They have been shown to take part in a wide variety of different physiological processes in eukaryotic organisms and are thought to be toxic at high concentrations. Ceramide is synthesized by condensation of the sphingoid base sphinganine and a fatty acyl CoA by ceramide synthases, a family of enzymes that differ in their specificity for the length of the acyl CoA substrate. We have engineered a yeast strain where the endogenous ceramide synthase has been replaced by one of the putative enzymes from cotton. As a result, the yeast strain produces C18 rather than C26 ceramides showing that the cotton protein is a bona fide ceramide synthase with specificity towards C18 acyl CoA. Strikingly, the accumulation of C18 ceramide is not toxic in Saccharomyces cerevisiae. This allows survival of the yeast after deletion of the normally essential AUR1 (inositol phosphorylceramide synthase) gene permitting us to address the essential roles of sphingolipids. Deletion of AUR1 allows cell growth, but leads to a defect in cytokinesis, which takes twice as long as in wild-type strains. Nuclear division and recruitment of septins is apparently not affected, but cytokinesis is delayed and cell separation is incomplete.     

Evolutionary patterns of RNA-based duplication in non-mammalian chordates

The role of RNA-based duplication, or retroposition, in the evolution of new gene functions in mammals, plants, and Drosophila has been widely reported. However, little is known about RNA-based duplication in non-mammalian chordates. In this study, we screened ten non-mammalian chordate genomes for retrocopies and investigated their evolutionary patterns. We identified numerous retrocopies in these species. Examination of the age distribution of these retrocopies revealed no burst of young retrocopies in ancient chordate species. Upon comparing these non-mammalian chordate species to the mammalian species, we observed that a larger fraction of the non-mammalian retrocopies was under strong evolutionary constraints than mammalian retrocopies are, as evidenced by signals of purifying selection and expression profiles. For the Western clawed frog, Medaka, and Sea squirt, many retrogenes have evolved gonad and brain expression patterns, similar to what was observed in human. Testing of retrogene movement in the Medaka genome, where the nascent sex chrosomes have been well assembled, did not reveal any significant gene movement. Taken together, our analyses demonstrate that RNA-based duplication generates many functional genes and can make a significant contribution to the evolution of non-mammalian genomes.     

Evolutionary dynamics of invasion and escape

Whenever life wants to invade a new habitat or escape from a lethal selection pressure, some mutations may be necessary to yield sustainable replication. We imagine situations like (i) a parasite infecting a new host, (ii) a species trying to invade a new ecological niche, (iii) cancer cells escaping from chemotherapy, (iv) viruses or microbes evading anti-microbial therapy, and also (v) the repeated attempts of combinatorial chemistry in the very beginning of life to produce self-replicating molecules. All such seemingly unrelated situations have a common structure in terms of Darwinian dynamics: a replicator with a basic reproductive ratio less than one attempts to find some mutations that allow indefinite survival. We develop a general theory, based on multitype branching processes, to describe the evolutionary dynamics of invasion and escape.     

Structure and expression of ferritin genes in a human promyelocytic cell line that differentiates in vitro.

HL-60 is a human promyelocytic cell line with the capability of differentiating in vitro to give neutrophils, macrophages, or eosinophils. We screened libraries of HL-60 cDNA clones representing different time points during these differentiation processes to isolate clones corresponding to mRNAs whose expression is regulated during terminal differentiation. Upon sequencing this group of regulated clones, one clone encoding the heavy subunit and two clones encoding the light subunit of human ferritin were identified by reference to published amino acid sequences. Southern blot analyses showed that these clones are encoded by distinct multigene families. These clones identify two mRNAs whose ratios vary in a complex manner during both neutrophil and macrophage differentiation.     

The Ag-NOR proteins and transcription and duplication of ribosomal genes in mammalian cell nucleoli

The relationship between the Ag-NOR (silver-stained Nucleolar Organizer Region) proteins and the functional-structural organization of the nucleolar ribosomal chromatin was studied in regenerating and cortisol-stimulated rat hepatocytes. Statistical analysis of Ag-NOR proteins, carried out with an automated image analyzer, indicated that in regenerating rat hepatocytes the quantity of Ag-NOR proteins mainly increased between the 4th and 12th h of regeneration, reaching a level twice that of resting hepatocytes. Also the synthesis of pre-ribosomal RNA (pre-rRNA) was stimulated after the 4th h of regeneration. Cycloheximide administered to rats at a dose of 0.025 mg/100 g body weight (bw) prevented any increase in Ag-NOR proteins but did not hinder the stimulation of pre-rRNA synthesis. In 8 h cortisol-stimulated hepatocytes no significant change in amount of Ag-NOR protein was observed whereas pre-rRNA synthesis was highly increased as in 12 h regenerating hepatocytes. These results indicated that in rat hepatocytes Ag-NOR proteins and stimulation of pre-rRNA synthesis are not related. The relationship between the Ag-NOR proteins and the distribution of the completely extended intranucleolar ribosomal chromatin was also studied in regenerating rat hepatocytes. At 12 h after partial hepatectomy an increased amount of completely extended ribosomal chromatin was observed, contemporaneously with an increased quantity of Ag-NOR proteins. These ribosomal chromatin changes preceded the beginning of DNA synthesis and were prevented by cycloheximide-induced inhibition of protein synthesis.     

Paleopolyploidy and gene duplication in soybean and other legumes

Two of the most important observations from whole-genome sequences have been the high rate of gene birth and death and the prevalence of large-scale duplication events, including polyploidy. There is also a growing appreciation that polyploidy is more than the sum of the gene duplications it creates, in part because polyploidy duplicates the members of entire regulatory networks. Thus, it may be important to distinguish paralogs that are produced by individual gene duplications from the homoeologous sequences produced by (allo)polyploidy. This is not a simple task, for several reasons, including the chromosomally cryptic nature of many duplications and the variable rates of gene evolution. Recent progress has been made in understanding patterns of gene and genome duplication in the legume family, specifically in soybean.     

Evolutionary conservation of RecA genes in relation to protein structure and function.

Functional and structural regions inferred from the Escherichia coli R ecA protein crystal structure and mutation studies are evaluated in terms of evolutionary conservation across 63 RecA eubacterial sequences. Two paramount segments invariant in specific amino acids correspond to the ATP-binding A site and the functionally unassigned segment from residues 145 to 149 immediately carboxyl to the ATP hydrolysis B site. Not only are residues 145 to 149 conserved individually, but also all three-dimensional structural neighbors of these residues are invariant, strongly attesting to the functional or structural importance of this segment. The conservation of charged residues at the monomer-monomer interface, emphasizing basic residues on one surface and acidic residues on the other, suggests that RecA monomer polymerization is substantially mediated by electrostatic interactions. Different patterns of conservation also allow determination of regions proposed to interact with DNA, of LexA binding sites, and of filament-filament contact regions. Amino acid conservation is also compared with activities and properties of certain RecA protein mutants. Arginine 243 and its strongly cationic structural environment are proposed as the major site of competition for DNA and LexA binding to RecA. The conserved acidic and glycine residues of the disordered loop L1 and its proximity to the RecA acidic monomer interface suggest its involvement in monomer-monomer interactions rather than DNA binding. The conservation of various RecA positions and regions suggests a model for RecA-double-stranded DNA interaction and other functional and structural assignments.