Your search keyword '"infection biology"' showing total 5 results

1. Visualization of Three Sclerotiniaceae Species Pathogenic on Onion Reveals Distinct Biology and Infection Strategies

Author

Maikel B F Steentjes, Sander Langebeeke, Olga E. Scholten, Jan A. L. van Kan, Sebastian Tonn, and Hilde Coolman

Subjects

0106 biological sciences, 0301 basic medicine, Allium cepa, Botrytis aclada, Botrytis squamosa, white rot, Plant Roots, 01 natural sciences, fluorescence microscopy, Conidium, lcsh:Chemistry, Infection biology, Sclerotium cepivorum, Onions, lcsh:QH301-705.5, onion, Spectroscopy, Fluorescence microscopy, biology, food and beverages, General Medicine, Computer Science Applications, Horticulture, neck rot, Neck rot, Botrytis, Onion, Sclerotium, Leaf blight, Catalysis, Article, Inorganic Chemistry, 03 medical and health sciences, Ascomycota, Sclerotiniaceae, Blight, Physical and Theoretical Chemistry, Molecular Biology, Laboratorium voor Nematologie, Plant Diseases, Organic Chemistry, fungi, biology.organism_classification, Laboratorium voor Phytopathologie, Plant Breeding, 030104 developmental biology, lcsh:Biology (General), lcsh:QD1-999, Laboratory of Phytopathology, infection biology, White rot, EPS, Laboratory of Nematology, leaf blight, 010606 plant biology & botany

Abstract

Botrytis squamosa, Botrytis aclada, and Sclerotium cepivorum are three fungal species of the family Sclerotiniaceae that are pathogenic on onion. Despite their close relatedness, these fungi cause very distinct diseases, respectively called leaf blight, neck rot, and white rot, which pose serious threats to onion cultivation. The infection biology of neck rot and white rot in particular is poorly understood. In this study, we used GFP-expressing transformants of all three fungi to visualize the early phases of infection. B. squamosa entered onion leaves by growing either through stomata or into anticlinal walls of onion epidermal cells. B. aclada, known to cause post-harvest rot and spoilage of onion bulbs, did not penetrate the leaf surface but instead formed superficial colonies which produced new conidia. S. cepivorum entered onion roots via infection cushions and appressorium-like structures. In the non-host tomato, S. cepivorum also produced appressorium-like structures and infection cushions, but upon prolonged contact with the non-host the infection structures died. With this study, we have gained understanding in the infection biology and strategy of each of these onion pathogens. Moreover, by comparing the infection mechanisms we were able to increase insight into how these closely related fungi can cause such different diseases.

Published

2021

2. Visualization of Three Sclerotiniaceae Species Pathogenic on Onion Reveals Distinct Biology and Infection Strategies.

Author

Steentjes, Maikel B. F., Tonn, Sebastian, Coolman, Hilde, Langebeeke, Sander, Scholten, Olga E., van Kan, Jan A. L., Schirawski, Jan, and Perlin, Michael H.

Subjects

*ONIONS, *BIOLOGY, *ONION growing, *SPECIES, *VISUALIZATION, *INFECTION

Abstract

Botrytis squamosa, Botrytis aclada, and Sclerotium cepivorum are three fungal species of the family Sclerotiniaceae that are pathogenic on onion. Despite their close relatedness, these fungi cause very distinct diseases, respectively called leaf blight, neck rot, and white rot, which pose serious threats to onion cultivation. The infection biology of neck rot and white rot in particular is poorly understood. In this study, we used GFP-expressing transformants of all three fungi to visualize the early phases of infection. B. squamosa entered onion leaves by growing either through stomata or into anticlinal walls of onion epidermal cells. B. aclada, known to cause post-harvest rot and spoilage of onion bulbs, did not penetrate the leaf surface but instead formed superficial colonies which produced new conidia. S. cepivorum entered onion roots via infection cushions and appressorium-like structures. In the non-host tomato, S. cepivorum also produced appressorium-like structures and infection cushions, but upon prolonged contact with the non-host the infection structures died. With this study, we have gained understanding in the infection biology and strategy of each of these onion pathogens. Moreover, by comparing the infection mechanisms we were able to increase insight into how these closely related fungi can cause such different diseases. [ABSTRACT FROM AUTHOR]

Published

2021

3. Keeping in Touch with Type-III Secretion System Effectors: Mass Spectrometry-Based Proteomics to Study Effector–Host Protein–Protein Interactions.

Author

Meyer, Margaux De, Ryck, Joren De, Goormachtig, Sofie, and Van Damme, Petra

Subjects

*PROTEIN-protein interactions, *SECRETION, *PROTEOMICS, *COMMUNICABLE diseases, *BIOLOGY, *PATHOLOGY

Abstract

Manipulation of host cellular processes by translocated bacterial effectors is key to the success of bacterial pathogens and some symbionts. Therefore, a comprehensive understanding of effectors is of critical importance to understand infection biology. It has become increasingly clear that the identification of host protein targets contributes invaluable knowledge to the characterization of effector function during pathogenesis. Recent advances in mapping protein–protein interaction networks by means of mass spectrometry-based interactomics have enabled the identification of host targets at large-scale. In this review, we highlight mass spectrometry-driven proteomics strategies and recent advances to elucidate type-III secretion system effector–host protein–protein interactions. Furthermore, we highlight approaches for defining spatial and temporal effector–host interactions, and discuss possible avenues for studying natively delivered effectors in the context of infection. Overall, the knowledge gained when unravelling effector complexation with host factors will provide novel opportunities to control infectious disease outcomes. [ABSTRACT FROM AUTHOR]

Published

2020

4. Zebrafish as a Model for Fish Diseases in Aquaculture.

Author

Jørgensen, Louise von Gersdorff

Subjects

FISH farming, FISH diseases, ZEBRA danio, BRACHYDANIO, AQUACULTURE, PARASITIC diseases, VIRUS diseases

Abstract

The use of zebrafish as a model for human conditions is widely recognized. Within the last couple of decades, the zebrafish has furthermore increasingly been utilized as a model for diseases in aquacultured fish species. The unique tools available in zebrafish present advantages compared to other animal models and unprecedented in vivo imaging and the use of transgenic zebrafish lines have contributed with novel knowledge to this field. In this review, investigations conducted in zebrafish on economically important diseases in aquacultured fish species are included. Studies are summarized on bacterial, viral and parasitic diseases and described in relation to prophylactic approaches, immunology and infection biology. Considerable attention has been assigned to innate and adaptive immunological responses. Finally, advantages and drawbacks of using the zebrafish as a model for aquacultured fish species are discussed. [ABSTRACT FROM AUTHOR]

Published

2020

5. Microtubules in Influenza Virus Entry and Egress.

Author

Simpson, Caitlin and Yamauchi, Yohei

Subjects

*INFLUENZA A virus, *MICROTUBULES, *VIRUS diseases, *HOST-virus relationships, *CYTOLOGY, *VIRAL replication

Abstract

Influenza viruses are respiratory pathogens that represent a significant threat to public health, despite the large-scale implementation of vaccination programs. It is necessary to understand the detailed and complex interactions between influenza virus and its host cells in order to identify successful strategies for therapeutic intervention. During viral entry, the cellular microenvironment presents invading pathogens with a series of obstacles that must be overcome to infect permissive cells. Influenza hijacks numerous host cell proteins and associated biological pathways during its journey into the cell, responding to environmental cues in order to successfully replicate. The cellular cytoskeleton and its constituent microtubules represent a heavily exploited network during viral infection. Cytoskeletal filaments provide a dynamic scaffold for subcellular viral trafficking, as well as virus-host interactions with cellular machineries that are essential for efficient uncoating, replication, and egress. In addition, influenza virus infection results in structural changes in the microtubule network, which itself has consequences for viral replication. Microtubules, their functional roles in normal cell biology, and their exploitation by influenza viruses will be the focus of this review. [ABSTRACT FROM AUTHOR]

Published

2020