Here we report the genome sequence of the honeybee Apis mellifera, a key model for social behaviour and essential to global ecology through pollination. Compared with other sequenced insect genomes, the A. mellifera genome has high A+T and CpG contents, lacks major transposon families, evolves more slowly, and is more similar to vertebrates for circadian rhythm, RNA interference and DNA methylation genes, among others. Furthermore, A. mellifera has fewer genes for innate immunity, detoxification enzymes, cuticle-forming proteins and gustatory receptors, more genes for odorant receptors, and novel genes for nectar and pollen utilization, consistent with its ecology and social organization. Compared to Drosophila, genes in early developmental pathways differ in Apis, whereas similarities exist for functions that differ markedly, such as sex determination, brain function and behaviour. Population genetics suggests a novel African origin for the species A. mellifera and insights into whether Africanized bees spread throughout the New World via hybridization or displacement.
Tardigrades, also known as water bears, are small aquatic animals. Some tardigrade species tolerate almost complete dehydration and exhibit extraordinary tolerance to various physical extremes in the dehydrated state. Here we determine a high-quality genome sequence of Ramazzottius varieornatus, one of the most stress-tolerant tardigrade species. Precise gene repertoire analyses reveal the presence of a small proportion (1.2% or less) of putative foreign genes, loss of gene pathways that promote stress damage, expansion of gene families related to ameliorating damage, and evolution and high expression of novel tardigrade-unique proteins. Minor changes in the gene expression profiles during dehydration and rehydration suggest constitutive expression of tolerance-related genes. Using human cultured cells, we demonstrate that a tardigrade-unique DNA-associating protein suppresses X-ray-induced DNA damage by ∼40% and improves radiotolerance. These findings indicate the relevance of tardigrade-unique proteins to tolerability and tardigrades could be a bountiful source of new protection genes and mechanisms.
Tardigrades are able to tolerate almost complete dehydration by reversibly switching to an ametabolic state. This ability is called anhydrobiosis. In the anhydrobiotic state, tardigrades can withstand various extreme environments including space, but their molecular basis remains largely unknown. Late embryogenesis abundant (LEA) proteins are heat-soluble proteins and can prevent protein-aggregation in dehydrated conditions in other anhydrobiotic organisms, but their relevance to tardigrade anhydrobiosis is not clarified. In this study, we focused on the heat-soluble property characteristic of LEA proteins and conducted heat-soluble proteomics using an anhydrobiotic tardigrade. Our heat-soluble proteomics identified five abundant heat-soluble proteins. All of them showed no sequence similarity with LEA proteins and formed two novel protein families with distinct subcellular localizations. We named them Cytoplasmic Abundant Heat Soluble (CAHS) and Secretory Abundant Heat Soluble (SAHS) protein families, according to their localization. Both protein families were conserved among tardigrades, but not found in other phyla. Although CAHS protein was intrinsically unstructured and SAHS protein was rich in β-structure in the hydrated condition, proteins in both families changed their conformation to an α-helical structure in water-deficient conditions as LEA proteins do. Two conserved repeats of 19-mer motifs in CAHS proteins were capable to form amphiphilic stripes in α-helices, suggesting their roles as molecular shield in water-deficient condition, though charge distribution pattern in α-helices were different between CAHS and LEA proteins. Tardigrades might have evolved novel protein families with a heat-soluble property and this study revealed a novel repertoire of major heat-soluble proteins in these anhydrobiotic animals.
Worker honeybees change their behaviour from the role of nurse to that of forager with age. We have isolated cDNA clones for two honeybee (Apis mellifera L.) genes, encoding a-amylase and glucose oxidase homologues, that are expressed in the hypopharyngeal gland of forager bees. The predicted amino acid sequence of the putative Apis amylase showed 60.5% identity with Drosophila melanogaster a-amylase, whereas that of Apis glucose oxidase showed 23.8% identity with Aspergillus niger glucose oxidase. To determine whether the isolated cDNAs actually encode these enzymes, we purified amylase and glucose oxidase from homogenized forager-bee hypopharyngeal glands. We sequenced the N-terminal regions of the purified enzymes and found that they matched the corresponding cDNAs. mRNAs for both enzymes were detected by Northern blotting in the hypopharyngeal gland of the forager bee but not in the nurse-bee gland. These results clearly indicate that expression of the genes for these carbohydrate-metabolizing enzymes, which are needed to process nectar into honey, in the hypopharyngeal gland is associated with the age-dependent role change of the worker.Keywords: amylase; behaviour; gene expression; glucose oxidase; honeybee.The honeybee (Apis mellifera L.) is a social insect and its colony is composed of a queen, drones, and workers. Workers perform almost all of the tasks in the colony except egg laying, but the tasks performed by an individual worker change depending on age after eclosion (age polyethism). The life-span of a worker bee is usually 30±40 days. Young workers (nurse bees, generally less than 14 days posteclosion) take care of their brood by synthesizing and secreting bee milk (royal jelly), whereas older workers (foragers, more than 10 days posteclosion) forage for nectar and process it into honey. They also have an intervening period of work in the hive devoted to other duties such as comb-building (days 10±27) [1±5]. In parallel with this age-dependent role change, physiological changes occur in certain organs of the worker. For example, the hypopharyngeal gland, which is believed to synthesize bee milk [6±8], is well developed in the nurse bee but shrinks in the forager, which then develops the ability to hydrolyse the sucrose of nectar into glucose and fructose [4,9].Previously, we purified three major proteins (of 50, 56 and 64 kDa) from homogenates of nurse-bee glands, and identified them as bee-milk proteins [10,11]. cDNA cloning revealed that the 50-and 64-kDa proteins (identical to RJP57-1) and RJP57-2, reported by Klaudiny et al. [12,13], are structurally related. mRNA for the 64-kDa protein is present in the nurse-bee gland but not in the forager-bee gland. By contrast, mRNA for the 56-kDa protein is present in the glands of both nurse and forager bees although the 56-kDa protein is present only in the nurse-bee gland, suggesting that expression of the 56-kDa protein is regulated at the translational level [11]. We also purified a major 70-kDa protein that is present only in the forager-bee gland ...
Major proteins synthesized in the hypopharyngeal gland of the worker honeybee change from bee-milk proteins to alpha-glucosidase in accordance with the age-dependent role change of the worker bee. Previously, we showed that the gene for alpha-glucosidase is expressed specifically in the forager-bee gland [Ohashi, K., Sawata, M., Takeuchi, H., Natori, S. & Kubo, T. (1996) Biochem. Biophys. Res. Commun. 221, 380-385]. Here, we describe the isolation and analysis of cDNAs for two bee-milk 56-kDa and 64-kDa proteins. The 56-kDa protein was a glycoprotein which shared 63.2% and 56.9% amino acid sequence identities with proteins encoded by cDNA for royal-jelly-related protein 57-1 (pRJP57-1) and pRJP57-2. The 64-kDa protein cDNA was identical to pRJP57-1. Thus, these bee-milk proteins seem to form a structurally related protein family. The gene for the 64-kDa protein/RJP57-1 was expressed specifically in the nurse-bee gland, whereas that for the 56-kDa protein was expressed in both the nurse-bee and forager-bee glands. mRNAs for the 56-kDa and 64-kDa proteins were detected by in situ hybridization in a whole acinus of the nurse-bee gland, whereas mRNAs for the 56-kDa protein and alpha-glucosidase were detected in that of the forager-bee gland. Therefore, the individual secretory cells of the acinus of the hypopharyngeal gland were shown to express these genes differently with the age-dependent role change of the worker bee.
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