A powerful in vivo alternative model in scientific research: Galleria mellonella

Singkum, Pantira; Suwanmanee, San; Pumeesat, Potjaman; Luplertlop, Natthanej

doi:10.1556/030.66.2019.001

Cited by 49 publications

(59 citation statements)

References 114 publications

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“…This model allows the evaluation of virulence factors, anti-fungal agents and immune response to a pathogen. Compared to other animal models, G. mellonella larvae are easy to handle, cheap, have no ethical limitations, and their innate immune system is similar to that of humans (Fuchs et al, 2010;Pereira et al, 2018;Singkum et al, 2019;Trevijano-Contador and Zaragoza, 2019). Besides, as shown in this study, larvae can be easily roomed at the desired temperature in an incubator, allowing the researchers to have better control of the experimental condition and to get reliable and reproducible data.…”

Section: Discussionmentioning

confidence: 92%

“…One of the advantages of using G. mellonella larvae as a model of host-pathogen interaction is the versatility of methods of inoculation, which can be topical (Scully and Bidochka, 2005), oral (Freitak et al, 2014) or the most common, microinjection (Eisenman et al, 2014;Amorim-Vaz et al, 2015;Kloezen et al, 2015;Wuensch et al, 2018;Sheehan and Kavanagh, 2019). Some other advantages include the feasibility of handling larvae due to their size, the fact that it is not necessary to feed them since they stop feeding in the fifth instar when experiments start (Singkum et al, 2019), the exclusion of ethical implications like those used in mammalian models, the ease of following-up on the progress of infection due to the use of standardized health scores (Champion et al, 2018), and the good antifungal immune response that includes cellular and humoral components (Kay et al, 2019;Trevijano-Contador and Zaragoza, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Galleria mellonella as a Novelty in vivo Model of Host-Pathogen Interaction for Malassezia furfur CBS 1878 and Malassezia pachydermatis CBS 1879

Torres

Pinzón

Rey

et al. 2020

Front. Cell. Infect. Microbiol.

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Section: Discussionmentioning

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Galleria mellonella as a Novelty in vivo Model of Host-Pathogen Interaction for Malassezia furfur CBS 1878 and Malassezia pachydermatis CBS 1879

Torres

Pinzón

Rey

et al. 2020

Front. Cell. Infect. Microbiol.

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“…This strategy leads to reducing the use of mammals and the replacement of these with alternative models; like computer, in vitro, alternative vertebrate ( Danio rerio ) [ 100 ], and invertebrate models [ 101 ]. In general, invertebrate alternatives used to model fungal infections like amoeboid models [ 53 , 102 ], Caenorhabditis elegans [ 103 , 104 , 105 ], Drosophila melanogaster [ 63 , 106 , 107 ], Tenebrio molitor [ 108 ], Bombyx mori [ 60 ], and Galleria mellonella [ 65 , 67 , 109 , 110 ] ( Figure 1 and Table 1 ) have gained importance, amongst others, as these present an innate immune response similar to that found in mammals. Furthermore, microbial virulence factors play similar roles in mammals and invertebrate systems [ 53 , 106 , 111 ].…”

Section: Infection Models As a Way To Understand Host–microbe Intementioning

confidence: 99%

In Vitro or In Vivo Models, the Next Frontier for Unraveling Interactions between Malassezia spp. and Hosts. How Much Do We Know?

Torres

Cock

Ramírez

2020

JoF

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Malassezia is a lipid-dependent genus of yeasts known for being an important part of the skin mycobiota. These yeasts have been associated with the development of skin disorders and cataloged as a causal agent of systemic infections under specific conditions, making them opportunistic pathogens. Little is known about the host–microbe interactions of Malassezia spp., and unraveling this implies the implementation of infection models. In this mini review, we present different models that have been implemented in fungal infections studies with greater attention to Malassezia spp. infections. These models range from in vitro (cell cultures and ex vivo tissue), to in vivo (murine models, rabbits, guinea pigs, insects, nematodes, and amoebas). We additionally highlight the alternative models that reduce the use of mammals as model organisms, which have been gaining importance in the study of fungal host–microbe interactions. This is due to the fact that these systems have been shown to have reliable results, which correlate with those obtained from mammalian models. Examples of alternative models are Caenorhabditis elegans, Drosophila melanogaster, Tenebrio molitor, and Galleria mellonella. These are invertebrates that have been implemented in the study of Malassezia spp. infections in order to identify differences in virulence between Malassezia species.

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“…Yet, to date, pathogen in vivo transcriptome studies from G. mellonella have been confined to fungal pathogens only, including Candida albicans (Amorim-Vaz et al, 2015) and entomopathogenic Beauveria bassiana (Chen et al, 2018). Since the immune system of G. mellonella consists of both cellular (i.e., hemocytes) and humoral components (Singkum et al, 2019; Wojda, 2017), the intrahemocoelic infection is useful to characterize host-dependent genome-wide transcriptional modulation by MH96 in response to three stages of infection using a time-resolved approach.…”

Section: Introductionmentioning

confidence: 99%

In vivotranscriptome analysis provides insights into host-dependent expression of virulence factors byYersinia entomophagaMH96, during infection ofGalleria mellonella

Paulson

O’Callaghan

Zhang³

et al. 2020

Preprint

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The function of microbes can be inferred from knowledge of genes specifically expressed in natural environments. Here we report the in vivo transcriptome of the entomopathogenic bacterium Yersinia entomophaga MH96, captured during three stages of intrahemocoelic infection in Galleria mellonella. A total of 1,285 genes were significantly upregulated by MH96 during infection; 829 genes responded to in vivo conditions during at least one stage of infection, 289 responded during two stages of infection and 167 transcripts responded throughout all three stages of infection. Genes upregulated during the earliest infection stage included components of the insecticidal toxin complex Yen-TC (chi1, chi2 and yenC1), genes for rearrangement hotspot element containing protein yenC3, cytolethal distending toxin cdtAB and vegetative insecticidal toxin vip2. Genes more highly expressed throughout the infection cycle included the putative heat-stable enterotoxin yenT and three adhesins (usher-chaperone fimbria, filamentous hemagglutinin and an AidA-like secreted adhesin). Clustering and functional enrichment of gene expression data also revealed expression of genes encoding type III and VI secretion system-associated effectors. Together these data provide insight into the pathobiology of MH96 and serve as an important resource supporting efforts to identify novel insecticidal agents.

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A powerful in vivo alternative model in scientific research: Galleria mellonella

Cited by 49 publications

References 114 publications

Galleria mellonella as a Novelty in vivo Model of Host-Pathogen Interaction for Malassezia furfur CBS 1878 and Malassezia pachydermatis CBS 1879

Galleria mellonella as a Novelty in vivo Model of Host-Pathogen Interaction for Malassezia furfur CBS 1878 and Malassezia pachydermatis CBS 1879

In Vitro or In Vivo Models, the Next Frontier for Unraveling Interactions between Malassezia spp. and Hosts. How Much Do We Know?

In vivotranscriptome analysis provides insights into host-dependent expression of virulence factors byYersinia entomophagaMH96, during infection ofGalleria mellonella

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