Determination of Residues Responsible for Substrate and Product Specificity of Solanum habrochaites Short-Chain cis-Prenyltransferases

Prenyl residues confer divergent biological activities such as antipathogenic and antiherbivorous activities on phenolic compounds, including flavonoids, coumarins, and xanthones. To date, about 1,000 prenylated phenolics have been isolated, with these compounds containing various prenyl residues. However, all currently described plant prenyltransferases (PTs) have been shown specific for dimethylallyl diphosphate as the prenyl donor, while most of the complementary DNAs encoding these genes have been isolated from the Leguminosae. In this study, we describe the identification of a novel PT gene from lemon (Citrus limon), ClPT1, belonging to the homogentisate PT family. This gene encodes a PT that differs from other known PTs, including flavonoid-specific PTs, in polypeptide sequence. This membrane-bound enzyme was specific for geranyl diphosphate as the prenyl donor and coumarin as the prenyl acceptor. Moreover, the gene product was targeted to plastid in plant cells. To our knowledge, this is the novel aromatic PT specific to geranyl diphosphate from citrus species.Prenylation is an important derivatization of plant aromatics, contributing to the chemical diversification of phenolic secondary metabolites in plants due to differences in prenylation positions, prenyl chain lengths, and further modifications of prenyl chains. To date, about 1,000 prenylated aromatic compounds have been isolated as biologically active substances from various plant species, including many medicinal plants.Coumarins (α-benzopyrones) are a large group of plant secondary metabolites. Many biologically active coumarins are prenylated, with the prenyl residue enhancing the biological activities of the aromatic core compound. For example, imperatorin (dimethylallylated xanthotoxol), a strong inhibitor of a Manduca sexta midgut cytochrome P450, has 100-fold greater activity than the nonprenylated coumarin compound, suggesting that prenylation is involved in chemoprevention against biotic stress in plants (Neal and Wu, 1994). Prenylated compounds are also beneficial for human health. For example, geranylation of umbelliferone at the OH position to form auraptene results in a 25-fold enhancement of the inhibition of Epstein Barr virus activity, a test used to screen antitumor compounds (Murakami et al., 1997). Moreover, in tuberculosis, 8-geranyloxypsoralen was reported to decrease the growth rate of Mycobacterium smegmatis (Adams et al., 2006).There are many reports on the detection of prenyltransferase (PT) activities for coumarins in various plant species. For example, umbelliferone-dimethylallyltransferase activities were reported in cultured parsley (Petroselinum crispum) cells, Ruta graveolens, and Ammi majus, and plastidial localization of the enzyme activity is also reported (Ellis and Brown, 1974; Dhillon and Brown, 1976; Tietjen and Matern, 1983; Hamerski and Matern, 1988; Hamerski et al., 1990). In addition, bergaptol 5-O-geranyltransferase activity, which yields bergamottin, a major coumarin derivative, was characterized using the microsomal fraction of lemon (Citrus limon) peel flavedo, the outer part of the lemon fruit (Frérot and Decorzant, 2004; Munakata et al., 2012). In the lemon flavedo, 8-geranyltransferase activity for umbelliferone was also detected (Munakata et al., 2012). To date, only one gene encoding these enzymes has been described; this gene, which encodes a parsley PT (PcPT), was very recently isolated (Karamat et al., 2014).The first flavonoid-specific PT identified was naringenin 8-dimethylallyltransferase (SfN8DT1) from a leguminous medicinal plant, Sophora flavescens (Sasaki et al., 2008). Since then, genes encoding various flavonoid PTs have been identified in Leguminosae (Akashi et al., 2009; Sasaki et al., 2011; Shen et al., 2012). Although other prenylated aromatic compounds, including coumarins, xanthons, phenylpropanoids, and phloroglucinols, have been isolated from many plant species, no gene encoding a PT for those aromatics has been isolated, except for the gene encoding a phloroglucinol-specific enzyme (HlPT1) from hops (Humulus lupulus) and a the recently isolated coumarin dimethylallyltransferase from parsley (Tsurumaru et al., 2010, 2012; Karamat et al., 2014). These isolated plant aromatic PTs show strong preference for dimethylallyl diphosphate (DMAPP) as the prenyl donor substrate, although in nature, many geranylated phenolics and less farnesylated phenolics have been described. This raises questions about the enzymes and reaction mechanisms involved in the synthesis of these phenolic compounds, such as substrate specificity and prenylation sites. Better understanding of these reactions requires the identification of PTs with other enzymatic activities. It is also necessary to identify PTs producing prenylated phenolics in nonleguminosaeous plants. Four different tracks should be explored to identify enzymes that (1) recognize nonflavonoid substrates, e.g. coumarins, phenylpropanoids, and xanthons, (2) are specific for longer chain prenyl diphosphates such as geranyl diphosphate (GPP) and farnesyl diphosphate (FPP), (3) are from nonlegume origins, and (4) catalyze O-prenylation.Citrus species, including lemons, contain large quantities of geranylated coumarins. We therefore isolated a complementary DNA (cDNA) encoding a PT from lemon peel, identifying the novel PT-encoding gene ClPT1. Phylogenetic analysis showed that this enzyme shares homologies with homogentisate PTs involved in vitamin E and plastoquinone biosynthesis but is located in a new clade. We provide evidence showing that this unique enzyme is highly specific for GPP as a prenyl donor and coumarin as a prenyl acceptor. We also show that the gene product is targeted to plastid in plant cells.     

A Novel Functional Human Eukaryotic Translation Initiation Factor 4G

Mammalian eukaryotic translation initiation factor 4F (eIF4F) is a cap-binding protein complex consisting of three subunits: eIF4E, eIF4A, and eIF4G. In yeast and plants, two related eIF4G species are encoded by two different genes. To date, however, only one functional eIF4G polypeptide, referred to here as eIF4GI, has been identified in mammals. Here we describe the discovery and functional characterization of a closely related homolog, referred to as eIF4GII. eIF4GI and eIF4GII share 46% identity at the amino acid level and possess an overall similarity of 56%. The homology is particularly high in certain regions of the central and carboxy portions, while the amino-terminal regions are more divergent. Far-Western analysis and coimmunoprecipitation experiments were used to demonstrate that eIF4GII directly interacts with eIF4E, eIF4A, and eIF3. eIF4GII, like eIF4GI, is also cleaved upon picornavirus infection. eIF4GII restores cap-dependent translation in a reticulocyte lysate which had been pretreated with rhinovirus 2A to cleave endogenous eIF4G. Finally, eIF4GII exists as a complex with eIF4E in HeLa cells, because eIF4GII and eIF4E can be purified together by cap affinity chromatography. Taken together, our findings indicate that eIF4GII is a functional homolog of eIF4GI. These results may have important implications for the understanding of the mechanism of shutoff of host protein synthesis following picornavirus infection.     

When TRBP leaves Dicer at the alt‐’ER

The principle underlying miRNA silencing seems rather simple: Dicer is required for the biogenesis of endogenous miRNAs, and mature miRNAs at the RNA‐induced silencing complex, RISC, bind to targets by sequence complementary, inhibiting protein expression. However, research shows that there are many degrees of complexity to miRNA regulation. A new study by Antoniou et al 1 that is published in this issue of EMBO Reports explores an interesting neuron‐specific facet of miRNA biogenesis. We learn that in neuronal dendrites, the endoplasmic reticulum (ER) acts as a regulatory domain for the dynamic encounter of TRBP and Dicer, two proteins required for the biogenesis of miRNAs, thus affecting neuron morphogenesis.     

A case study of a shared/buy-in computing ecosystem

Many research institutions are deploying computing clusters based on a shared/buy-in paradigm. Such clusters combine shared computers, which are free to be used by all users, and buy-in computers, which are computers purchased by users for semi-exclusive use. The purpose of this paper is to characterize the typical behavior and performance of a shared/buy-in computing cluster, using data traces from the Shared Computing Cluster (SCC) at Boston University that runs under this paradigm as a case study. Among our main findings, we show that the semi-exclusive policy, which allows any SCC user to use idle buy-in resources for a limited time, increases the utilization of buy-in resources by 17.4%, thus significantly improving the performance of the system as a whole. We find that jobs allowed to run on idle buy-in resources arrive more frequently and run for a shorter time than other jobs. Finally, we identify the run time limit (i.e., the maximum time during which a job is allowed to use resources) and the type of parallel environment as two factors that have a significant impact on the different performance experienced by shared and buy-in jobs.     

The Genetics of Bene Israel from India Reveals Both Substantial Jewish and Indian Ancestry

The Bene Israel Jewish community from West India is a unique population whose history before the 18^th century remains largely unknown. Bene Israel members consider themselves as descendants of Jews, yet the identity of Jewish ancestors and their arrival time to India are unknown, with speculations on arrival time varying between the 8th century BCE and the 6th century CE. Here, we characterize the genetic history of Bene Israel by collecting and genotyping 18 Bene Israel individuals. Combining with 486 individuals from 41 other Jewish, Indian and Pakistani populations, and additional individuals from worldwide populations, we conducted comprehensive genome-wide analyses based on F_ST, principal component analysis, ADMIXTURE, identity-by-descent sharing, admixture linkage disequilibrium decay, haplotype sharing and allele sharing autocorrelation decay, as well as contrasted patterns between the X chromosome and the autosomes. The genetics of Bene Israel individuals resemble local Indian populations, while at the same time constituting a clearly separated and unique population in India. They are unique among Indian and Pakistani populations we analyzed in sharing considerable genetic ancestry with other Jewish populations. Putting together the results from all analyses point to Bene Israel being an admixed population with both Jewish and Indian ancestry, with the genetic contribution of each of these ancestral populations being substantial. The admixture took place in the last millennium, about 19–33 generations ago. It involved Middle-Eastern Jews and was sex-biased, with more male Jewish and local female contribution. It was followed by a population bottleneck and high endogamy, which can lead to increased prevalence of recessive diseases in this population. This study provides an example of how genetic analysis advances our knowledge of human history in cases where other disciplines lack the relevant data to do so.     

The genome sequence of the leaf-cutter ant Atta cephalotes reveals insights into its obligate symbiotic lifestyle

Leaf-cutter ants are one of the most important herbivorous insects in the Neotropics, harvesting vast quantities of fresh leaf material. The ants use leaves to cultivate a fungus that serves as the colony's primary food source. This obligate ant-fungus mutualism is one of the few occurrences of farming by non-humans and likely facilitated the formation of their massive colonies. Mature leaf-cutter ant colonies contain millions of workers ranging in size from small garden tenders to large soldiers, resulting in one of the most complex polymorphic caste systems within ants. To begin uncovering the genomic underpinnings of this system, we sequenced the genome of Atta cephalotes using 454 pyrosequencing. One prediction from this ant's lifestyle is that it has undergone genetic modifications that reflect its obligate dependence on the fungus for nutrients. Analysis of this genome sequence is consistent with this hypothesis, as we find evidence for reductions in genes related to nutrient acquisition. These include extensive reductions in serine proteases (which are likely unnecessary because proteolysis is not a primary mechanism used to process nutrients obtained from the fungus), a loss of genes involved in arginine biosynthesis (suggesting that this amino acid is obtained from the fungus), and the absence of a hexamerin (which sequesters amino acids during larval development in other insects). Following recent reports of genome sequences from other insects that engage in symbioses with beneficial microbes, the A. cephalotes genome provides new insights into the symbiotic lifestyle of this ant and advances our understanding of host-microbe symbioses.