Insect immunology and hematopoiesis

Hillyer, Julián F.

doi:10.1016/j.dci.2015.12.006

Cited by 367 publications

(311 citation statements)

References 252 publications

(377 reference statements)

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“…Some ant species exhibit an increased immune response and become more pathogen‐tolerant after mating (Castella, Christe, & Chapuisat, ; Galvez & Chapuisat, ). In insect immune response, insect hemocytes and antimicrobial peptides (AMPs) play important roles in defense (Hillyer, ; Viljakainen & Pamilo, ; Vlisidou & Wood, ). We found upregulated genes in queen brains representative of these pathways; astakine , a neuropeptide, likely induces hematopoiesis (Lin, Kim, Lee, Soderhall, & Soderhall, ; Lin & Soderhall, ; Lin, Soderhall, & Soderhall, ) and nc725 , which likely encodes an AMP (see below).…”

Section: Discussionmentioning

confidence: 99%

Brain gene expression analyses in virgin and mated queens of fire ants reveal mating‐independent and socially regulated changes

Calkins

Chen

Arora

et al. 2018

Ecology and Evolution

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Transcriptomes of dissected brains from virgin alate and dealate mated queens from polygyne fire ants (Solenopsis invicta) were analyzed and compared. Thirteen genes were upregulated in mated queen brain, and nine were downregulated. While many of the regulated genes were either uncharacterized or noncoding RNAs, those annotated genes included two hexamerin proteins, astakine neuropeptide, serine proteases, and serine protease inhibitors. We found that for select differentially expressed genes in the brain, changes in gene expression were most likely driven by the changes in physiological state (i.e., age, nutritional status, or dominance rank) or in social environment (released from influence of primer pheromone). This was concluded because virgins that dealated after being separated from mated queens showed similar patterns of gene expression in the brain as those of mated queens for hexamerin 1, astakine, and XR_850909. Abaecin (XR_850725), however, appears upregulated only after mating. Therefore, our findings contribute to distinguish how specific gene networks, especially those influenced by queen primer pheromone, are regulated in queen ants. Additionally, to identify brain signaling pathways, we mined the fire ant genome and compiled a list of G‐protein‐coupled receptors (GPCRs). The expression level of GPCRs and other genes in the “genetic toolkit” in the brains of virgin alates and mated dealate queens is reported.

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Section: Discussionmentioning

confidence: 99%

Brain gene expression analyses in virgin and mated queens of fire ants reveal mating‐independent and socially regulated changes

Calkins

Chen

Arora

et al. 2018

Ecology and Evolution

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“…The production and deposition of melanin at the site of injury may trap and kill invading microbes. The melanization process represents a coordinating interaction involving pattern recognition receptors, serine proteases, serine and enzymes that promote melanogenesis (Hillyer, ). During melanization reactions, soluble pattern recognition proteins promote the recognition of nonself objects associated with invading microbes (Matskevich et al, ; Wang et al, ; Stokes et al, ), which triggers sequential activation of a series of serine proteases and leads to the activation of the prophenoloxidase‐activating enzyme into its active form (In‐Kwon et al, ; Tokura et al, ).…”

Section: Ampsmentioning

confidence: 99%

“…During melanization reactions, soluble pattern recognition proteins promote the recognition of nonself objects associated with invading microbes (Matskevich et al, ; Wang et al, ; Stokes et al, ), which triggers sequential activation of a series of serine proteases and leads to the activation of the prophenoloxidase‐activating enzyme into its active form (In‐Kwon et al, ; Tokura et al, ). Afterwards, inactive prophenoloxidase (Pro‐PO) is activated into PO (An et al, ; Zhen et al, ; An et al, ; Lu et al, ), which participates in the melanization process as a catalyst (Christensen et al, ; Nappi et al, ; Hillyer, ; Sanzhaeva et al, ). A schematic of the pathway associated with the silkworm melanization mechanism is provided based on existing reports (Fig.…”

Section: Ampsmentioning

confidence: 99%

Research progress on the immune mechanism of the silkworm Bombyx mori

et al. 2018

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The silkworm Bombyx mori L., representing an important economic insect and one of the best models for studying insect immunity, possesses an efficient and sophisticated innate immune system against invasive microorganisms. The innate immune system basically includes humoural immunity and cellular immunity. The humoural immunity, which functions via molecules including humoural factors, lysozymes, phenoloxidase, hemolin, lectins and, in particular, antimicrobial peptides, plays a central role in eliminating the invading pathogens. The cellular immunity is primarily carried out and mediated by plasmatocytes and granular cells of haemocytes in the haemolymph, usually followed by melanization. Additionally, apoptosis, a primary viral defence for insects lacking adaptive immunity, comprises an important part of the silkworm immune system. Currently, there is still the lack of a comprehensive and systematic understanding of the molecular mechanisms of silkworm immunity. We review the latest research progress on silkworm immune mechanisms, including phenoloxidase‐dependent melanization and apoptosis, which is conducive to improving our understanding of the silkworm immune mechanism, clarifying the relationship of various immune mechanisms, and also providing a theoretical basis and reference for the future research of insect immunity.

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“…12 Hemolymph contains several types of cells, or hemocytes: (i) plasmatocytes and granulocytes, (ii) lamellocytes, and (iii) oenocytoids or crystal cells. 13 Phagocytosis, the engulfment of bacteria and other small particles, is performed by plasmatocytes ( Drosophila melanogaster ) or granulocytes ( Anopheles gambiae ). Some granulocytes facilitate agglutination, clumping pathogens and hemocytes together, or coagulation of hemolymph in response to wounding.…”

Section: Physiology Immunity and Vector-borne Pathogensmentioning

confidence: 99%

Arthropod Innate Immune Systems and Vector-Borne Diseases

2017

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Arthropods, especially ticks and mosquitoes, are the vectors for a number of parasitic and viral human diseases, including malaria, sleeping sickness, Dengue, and Zika, yet arthropods show tremendous individual variation in their capacity to transmit disease. A key factor in this capacity is the group of genetically encoded immune factors that counteract infection by the pathogen. Arthropod-specific pattern recognition receptors and protease cascades detect and respond to infection. Proteins such as antimicrobial peptides, thioester-containing proteins, and transglutaminases effect responses such as lysis, phagocytosis, melanization, and agglutination. Effector responses are initiated by damage signals such as reactive oxygen species signaling from epithelial cells and recognized by cell surface receptors on hemocytes. Antiviral immunity is primarily mediated by siRNA pathways but coupled with interferon-like signaling, antimicrobial peptides, and thioester-containing proteins. Molecular mechanisms of immunity are closely linked to related traits of longevity and fertility, and arthropods have the capacity for innate immunological memory. Advances in understanding vector immunity can be leveraged to develop novel control strategies for reducing the rate of transmission of both ancient and emerging threats to global health.

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Insect immunology and hematopoiesis

Cited by 367 publications

References 252 publications

Brain gene expression analyses in virgin and mated queens of fire ants reveal mating‐independent and socially regulated changes

Brain gene expression analyses in virgin and mated queens of fire ants reveal mating‐independent and socially regulated changes

Research progress on the immune mechanism of the silkworm Bombyx mori

Arthropod Innate Immune Systems and Vector-Borne Diseases

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