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Social insects are among the most successful and ecologically important animals on earth. The lifestyle of these insects has fascinated humans since prehistoric times. These species evolved a caste of workers that in most cases have no progeny. Some social insects have worker sub-castes that are morphologically specialized for discrete tasks. The organization of the social insect colony has been compared to the metazoan body. Males in the order Hymenoptera (bees, ants and wasps) are haploid, a situation which results in higher relatedness between female siblings. Sociality evolved many times within the Hymenoptera, perhaps spurred in part by increased relatedness that increases inclusive fitness benefits to workers cooperating to raise their sisters and brothers rather than reproducing themselves. But epigenetic processes may also have contributed to the evolution of sociality. The Hymenoptera provide opportunities for comparative study of species ranging from solitary to highly social. A more ancient clade of social insects, the termites (infraorder Isoptera) provide an opportunity to study alternative mechanisms of caste determination and lifestyles that are aided by an array of endosymbionts. This research topic explores the use of genome sequence data and genomic techniques to help us explore how sociality evolved in insects, how epigenetic processes enable phenotypic plasticity, and the mechanisms behind whether a female will become a queen or a worker.

sterile caste --- reproductive caste --- gene networks --- Isoptera --- phenotypic plasticity --- Polyethism --- Hymenoptera --- sex determination --- Eusocial --- parental effects

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The sterile insect technique (SIT) is an environment-friendly method of pest control that integrates well into area-wide integrated pest management (AW-IPM) programmes. A first of its kind, this book takes a generic, comprehensive, and global approach in describing the principles and practice of the SIT. The strengths and weaknesses, and successes and failures, of the SIT are evaluated openly and fairly from a scientific perspective. The SIT is applicable to some major pests of plant, animal and human health importance, and criteria are provided to guide in the selection of pests appropriate for the SIT. A great variety of subjects are covered, from the history of the SIT to improved prospects for its future application. The major chapters discuss the principles, technical components, and application of sterile insects. The four main strategic options in using the SIT — suppression, containment, prevention, and eradication — with examples of each option, are described in detail. Other chapters deal with supportive technologies, economic, environmental, and management considerations, and the socio-economic impact of AW-IPM programmes that integrate the SIT. This book provides a wealth of information and reference material never before available in one volume. It will be a standard reference on the subject for many years. The authors, from 19 countries, are highly experienced in the subject, and reflect the international character of SIT activities. Since no university offers courses on the SIT, the book’s audience will be mainly students in general animal and plant health courses, but the in-depth reviews of all aspects of the SIT and its integration into AW-IPM programmes will be of great value to researchers, teachers, animal and plant health practitioners, and policy makers.

Insect sterilization. --- Insect pests --- Biological control. --- Integrated control. --- Destructive insects --- Economic entomology --- Entomology, Economic --- Injurious insects --- Insects, Injurious and beneficial --- Arthropod pests --- Insects --- Veterinary entomology --- Biological control of insects --- Sterile-male technique (Insect control) --- Sterilization of insects --- Animal contraception --- Sterilization (Birth control) --- Biological control --- Control --- Entomology. --- Cytology --- Zoology. --- Biological Techniques. --- Research --- Methodology. --- Cell biology --- Cellular biology --- Biology --- Cells --- Cytologists --- Zoology --- Natural history --- Animals --- Biology—Technique.

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[Increasing evidence suggests that microbiota and especially the gut microbiota (the microbes inhabiting the gut including bacteria, archaea, viruses, and fungi) plays a key role in human physiology and pathology. Recent findings indicate how dysbiosis—an imbalance in the composition and organization of microbial populations—could severely impact the development of different medical conditions (from metabolic to mood disorders), providing new insights into the comprehension of diverse diseases, such as IBD, obesity, asthma, autism, stroke, diabetes, and cancer. Given that microbial cells in the gut outnumber host cells, microbiota influences human physiology both functionally and structurally. Microbial metabolites bridge various—even distant—areas of the organism by way of the immune and hormone system. For instance, it is now clear that the mutual interaction between the gastrointestinal tract and the brain (gut–brain axis), often involves gut microbiota, indicating that the crosstalk between the organism and its microbial residents represents a fundamental aspect of both the establishment and maintenance of healthy conditions. Moreover, it is crucial to recognize that beyond the intestinal tract, microbiota populates other host organs and tissues (e.g., skin and oral mucosa). We have edited this eBook with the aim of publishing manuscripts focusing on the impact of microbiota in the development of different diseases and their associated treatments.]

gastrointestinal diseases --- sterile inflammation --- n/a --- Staphylococcus spp. --- etiopathogenesis --- colitis --- Escherichia coli --- bacteriophages --- atopic dermatitis --- intravenous immunoglobulin G --- adaptive immunity --- 16S rRNA gene --- vaginal microbiota --- modularity --- innate immunity --- gut-liver axis --- disease activity --- immune system --- cytokines --- commensals --- Staphylococcus aureus --- dysbiosis --- fecal transplantation --- TLR mimicry --- etanercept --- dextran sulfate sodium --- CAR T-cell --- 3-dihydroxy-4-methoxyBenzaldehyde --- chemo free treatment --- Staphylococcus epidermis --- rheumatoid arthritis --- microbiome --- co-occurrence network --- immune epigenetics --- 2 --- autoimmunity --- superoxide dismutase --- precision medicine --- metabolism --- adoptive cell transfer (ACT) --- gut barrier --- antibiotics --- checkpoint inhibitors --- probiotics --- microbiota --- Candida albicans --- Enterococcus faecalis --- chronic liver diseases --- TCR --- anaerobic bacteria --- HSV2 --- bacteriocins --- methotrexate --- microbial interactions --- T cells --- virus --- mice --- lymphoid malignancies --- HPV --- macrophages --- anti-TNF-? --- inflammation --- chondroitin sulfate disaccharide --- immunotherapy --- genomics --- immuno-oncology --- diet --- aerobic bacteria --- immunological niche --- melanin --- health --- chemokines --- gut microbiota --- cutaneous immunity --- HIV --- TIL --- cancer --- global network

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The development of new plant varieties is a long and tedious process involving the generation of large seedling populations for the selection of the best individuals. While the ability of breeders to generate large populations is almost unlimited, the selection of these seedlings is the main factor limiting the generation of new cultivars. Molecular studies for the development of marker-assisted selection (MAS) strategies are particularly useful when the evaluation of the character is expensive, time-consuming, or with long juvenile periods. The papers published in the Special Issue “Plant Genetics and Molecular Breeding” report highly novel results and testable new models for the integrative analysis of genetic (phenotyping and transmission of agronomic characters), physiology (flowering, ripening, organ development), genomic (DNA regions responsible for the different agronomic characters), transcriptomic (gene expression analysis of the characters), proteomic (proteins and enzymes involved in the expression of the characters), metabolomic (secondary metabolites), and epigenetic (DNA methylation and histone modifications) approaches for the development of new MAS strategies. These molecular approaches together with an increasingly accurate phenotyping will facilitate the breeding of new climate-resilient varieties resistant to abiotic and biotic stress, with suitable productivity and quality, to extend the adaptation and viability of the current varieties.

n/a --- GA2ox7 --- cabbage --- OsGPAT3 --- oleic acid --- OsCDPK1 --- nutrient use efficiency --- stem borer --- yellow-green-leaf mutant --- branching --- epigenetics --- NPK fertilizers --- particle bombardment --- stress tolerance --- overexpression --- glycine --- heat-stress --- bulk segregant RNA-seq --- Prunus --- protein-protein interaction --- AdRAP2.3 --- plant architecture --- waterlogging stress --- genes --- Cucumis sativus L. --- Flower color --- resistance --- Tobacco --- gynomonoecy --- drought stress --- Brassica oleracea --- starch biosynthesis --- Overexpression --- WUS --- agronomic traits --- Ghd7 --- the modified MutMap method --- cry2A gene --- light-induced --- gene expression --- breeding --- Heterodera schachtii --- ABA --- Green tissue-specific expression --- subcellular localization --- squamosa promoter binding protein-like --- transcriptome --- FAD2 --- As3+ stress --- metallothionein --- flowering --- bisulfite sequencing --- tomato --- quantitative trait loci --- Promoter --- marker–trait association --- DEGs --- cytoplasmic male sterile --- Rosa rugosa --- MADS transcription factor --- yield --- P. suffruticosa --- CYC2 --- common wild rice --- Actinidia deliciosa --- gene-by-gene interaction --- Aechmea fasciata --- hybrid rice --- soybean --- R2R3-MYB --- bread wheat --- BRANCHED1 (BRC1) --- linoleic acid --- differentially expressed genes --- complex traits --- transgenic chrysanthemum --- D-genome --- Brassica --- candidate gene --- SmJMT --- gene expression pattern --- RNA-Seq --- candidate genes --- leaf shape --- Brassica napus --- recombination-suppressed region --- anthocyanin --- WRKY transcription factor --- Idesia polycarpa var --- single nucleotide polymorphism --- bud abortion --- QTL --- reproductive organ --- transient overexpression --- Elongated Internode (EI) --- sugarcane --- abiotic stress --- Oryza sativa L. --- RrGT2 gene --- Hd1 --- cZR3 --- cytoplasmic male sterility (CMS) --- seed development --- tapetum --- near-isogenic line (NIL) --- phytohormones --- TCP transcription factor --- pollen accumulation --- Anthocyanin --- WRKY --- quantitative trait loci (QTLs) --- salt stress --- floral scent --- sucrose --- Ogura-CMS --- root traits --- endosperm development --- Zea mays L. --- sesame --- Bryum argenteum --- AP2/ERF genes --- transcriptional regulation --- WB1 --- haplotype block --- broccoli --- agronomic efficiency --- durum wheat --- gene pyramiding --- Oryza sativa --- genetics --- flowering time --- Cicer arietinum --- Hs1pro-1 --- endosperm appearance --- phenolic acids --- anther wall --- bromeliad --- genomics --- transgenic --- DgWRKY2 --- Clone --- yield trait --- flower symmetry --- partial factor productivity --- rice --- molecular breeding --- genotyping-by-sequencing --- Chimonanthus praecox --- nectary --- Salvia miltiorrhiza --- pollen development --- regulation --- ZmES22 --- genome-wide association study --- VIGS --- iTRAQ --- genome-wide association study (GWAS) --- ethylene-responsive factor --- starch --- molecular markers --- rice quality --- Chrysanthemum morifolium --- marker-trait association