Calomys callosus: An Experimental Animal Model Applied to Parasitic Diseases Investigations of Public Health Concern

Rosa, Rafael Borges; Costa, Mylla Spirandelli da; Teixeira, Samuel Cota; Castro, Emilene Ferreira de; Dantas, Willyenne Marília; Ferro, Eloísa Amália Vieira; Silva, Murilo Vieira da

doi:10.3390/pathogens11030369

Cited by 4 publications

(6 citation statements)

References 85 publications

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“…A deeper knowledge of the biology of TGCs in cricetid rodents will contribute not only to clarify evolutionary aspects of maternal-fetal communication, but may increase our knowledge in different fields: 1) maternal tolerance and immunomodulation during trophoblast invasion and vascular remodelling; 2) how changes of gene copy number and their expression affect normal and abnormal cell differentiation, for which TGCs are an interesting model; 3) the distribution of histone variants such as H3.3, in the genome of TGCs; 4) the development of knockout models for genes of interest (including exclusive markers for specific TGC lineages), which could generate data regarding placental abnormalities; 5) since the placental trophoblasts are responsible for fetal protection, and infection of these cells is directly involved in the pathogenesis of several intracellular parasites, knowledge of TGC diversity in cricetids will be helpful for the establishment of effective laboratory models, as has been shown in Calomys callosus ( Costa et al, 2009 ; Rosa et al, 2022 ); and finally 6) exploration of specific TGC-lineages as models for cancer development and metastasis, especially using cell cultures and 3D models.…”

Section: Discussionmentioning

confidence: 99%

“…Primary TGCs Derived from mural trophectoderm and migrate to decidua Similar Phagocytic and may enlarge implantation chamber (Disse, (1906) Parietal TGCs Parietal yolk sac beneath Reichert's membrane; distinct layer between junctional zone and decidua; accumulation at placental margin Identical location in parietal yolk sac and between junctional zone and decidua Accumulation at margin described for several families of cricetids (Sansom, (1922); Pijnenborg, (1975); Favaron et al (2011) (Pijnenborg et al (1974), although uNK cells are more important (Croy et al (1996) Migratory TGCs Found in numerous locations including the uterine wall where they can survive postpartum Apart from early migration towards the spiral arteries, murine TGCs seem to wander less than in cricetids Prominent feature of cricetid placentation (Sansom, (1922); Ozdzenski and Mystkowka, (1976);Parkening, (1976); Copp and Clarke, (1988); Blankenship et al (1990); Ferro and Bevilacqua, (1994) Frontiers in Cell and Developmental Biology frontiersin.org aspects of maternal-fetal communication, but may increase our knowledge in different fields: 1) maternal tolerance and immunomodulation during trophoblast invasion and vascular remodelling; 2) how changes of gene copy number and their expression affect normal and abnormal cell differentiation, for which TGCs are an interesting model; 3) the distribution of histone variants such as H3.3, in the genome of TGCs; 4) the development of knockout models for genes of interest (including exclusive markers for specific TGC lineages), which could generate data regarding placental abnormalities; 5) since the placental trophoblasts are responsible for fetal protection, and infection of these cells is directly involved in the pathogenesis of several intracellular parasites, knowledge of TGC diversity in cricetids will be helpful for the establishment of effective laboratory models, as has been shown in Calomys callosus (Costa et al, 2009;Rosa et al, 2022); and finally 6) exploration of specific TGC-lineages as models for cancer development and metastasis, especially using cell cultures and 3D models.…”

Section: Notation Location Comparison To Mouse Further Commentsmentioning

confidence: 99%

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The trophoblast giant cells of cricetid rodents

Favaron

Carter

2023

Front. Cell Dev. Biol.

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Giant cells are a prominent feature of placentation in cricetid rodents. Once thought to be maternal in origin, they are now known to be trophoblast giant cells (TGCs). The large size of cricetid TGCs and their nuclei reflects a high degree of polyploidy. While some TGCs are found at fixed locations, others migrate throughout the placenta and deep into the uterus where they sometimes survive postpartum. Herein, we review the distribution of TGCs in the placenta of cricetids, including our own data from the New World subfamily Sigmodontinae, and attempt a comparison between the TGCs of cricetid and murid rodents. In both families, parietal TGCs are found in the parietal yolk sac and as a layer between the junctional zone and decidua. In cricetids alone, large numbers of TGCs, likely from the same lineage, accumulate at the edge of the placental disk. Common to murids and cricetids is a haemotrichorial placental barrier where the maternal-facing layer consists of cytotrophoblasts characterized as sinusoidal TGCs. The maternal channels of the labyrinth are supplied by trophoblast-lined canals. Whereas in the mouse these are lined largely by canal TGCs, in cricetids canal TGCs are interspersed with syncytiotrophoblast. Transformation of the uterine spiral arteries occurs in both murids and cricetids and spiral artery TGCs line segments of the arteries that have lost their endothelium and smooth muscle. Since polyploidization of TGCs can amplify selective genomic regions required for specific functions, we argue that the TGCs of cricetids deserve further study and suggest avenues for future research.

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Section: Discussionmentioning

confidence: 99%

Section: Notation Location Comparison To Mouse Further Commentsmentioning

confidence: 99%

The trophoblast giant cells of cricetid rodents

Favaron

Carter

2023

Front. Cell Dev. Biol.

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“…Host competence (i.e., the ability to become infected and infectious) has been demonstrated in the lab for four species: the Virginia oppossum, the large vesper mouse (Calomys callosus) , spix’s yellow toothed cavy (Galea spixii) , and the Mexican free-tailed bat (Tadarida brasiliensis) (Araujo Carreira et al, 2017; Barbosa et al, 2008; Berzunza-Cruz et al, 2015; Rosa et al, 2022). Our model suggests that these animals are also likely to be naturally infected in the wild; the large vesper mouse is one of the top predicted species for L. (Vianna) .…”

Section: Discussionmentioning

confidence: 99%

“…Host competence (i.e., the ability to become infected and infectious) has been demonstrated in the lab for four of the predicted species: the Virginia opossum (Didlephis virginiana), the large vesper mouse (Calomys callosus), spix's yellow toothed cavy (Galea spixii), and the Mexican free-tailed bat (Tadarida brasiliensis) (69,(73)(74)(75). Although host competence for these animals has been tested in the laboratory, infection/exposure has not been tested in the wild or animals have not tested positive in the wild (possibly due to minimal sampling of the species).…”

Section: Discussionmentioning

confidence: 99%

Phylogenetic and biogeographical traits predict unrecognized hosts of zoonotic leishmaniasis

Glidden

Murran

Silva

et al. 2022

Preprint

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Spatio-temporal distribution of leishmaniasis, a parasitic vector-borne zoonotic disease, is significantly impacted by land-use change and climate warming in the Americas. However, predicting and containing outbreaks is challenging as the zoonotic Leishmania system is highly complex: Leishmaniasis (visceral, cutaneous and muco-cutaneous) in humans is caused by up to 14 different Leishmania species, and the parasite is transmitted by dozens of sandfly species and is known to infect almost twice as many wildlife species. Despite the already broad known host range, new hosts are discovered almost annually and Leishmania transmission to humans occurs in absence of a known host. As such, the full range of Leishmania hosts is undetermined, inhibiting the use of ecological interventions limiting pathogen spread as well as accurately predicting the impact of global change on disease risk. Here, we employed a machine learning approach to generate trait profiles of known zoonotic Leishmania wildlife hosts (mammals that are naturally exposed and susceptible to infection) and used trait-profiles of known hosts to identify potentially unrecognized hosts. We found that biogeography, phylogenetic distance, and study effort best predicted Leishmania host status. Traits associated with global change, such as agricultural land-cover, urban land-cover, and climate, were among the top predictors of host status. Most notably, our analysis suggested zoonotic Leishmania hosts are significantly undersampled, as our model predicted just as many unrecognized hosts as unknown hosts. Overall, our analysis facilitates targeted surveillance strategies and improved understanding of the impact of global change on local transmission cycles.

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“…The easy and practical handling, low cost, and need for low concentration of interventions in the new drug discovery phase are advantages that increase the incidence of using these experimental models in studies focused on CD [63]. With pathogenesis similar to that of CD in humans (immunological, pathological, and physiological), it is essential to consider that models such as mice and rats may not accurately reflect the progression and manifestations of CD, with dependence on the strain used in infection, concentration, route, and form of the protozoan used in inoculum and the genetic background of the experimental model [63][64][65]. As an example, depending on the strain, inoculum, and experimental model used, infection in the acute experimental phase can result in up to 100% mortality rate, while for humans, the rate is 5% [63,66].…”

Section: Discussionmentioning

confidence: 99%

Neuroprotective Treatments for Digestive Forms of Chagas Disease in Experimental Models: A Systematic Review

Neto

Guerra

Rodrigues

et al. 2022

Oxidative Medicine and Cellular Longevity

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Chagas disease is an anthropozoonosis caused by the protozoan Trypanosoma cruzi and is characterized as a neglected disease. It is currently endemic in 21 countries on the Latin American continent, including Bolivia, Argentina, and Paraguay. Unfortunately, there are no optimally effective treatments that can reduce the damage caused in the digestive form of the disease, such as the neuronal destruction of the myenteric plexus of both the esophagus and the colon. Therefore, the objective of this systematic review was to report the possible pharmacological neuroprotective agents that were tested in murine models of the digestive form of Chagas disease. Inclusion criteria are in vivo experimental studies that used different murine models for digestive forms of Chagas disease related to pharmacological interventions with neuroprotective potential, without year and language restriction. On the other hand, the exclusion criteria were studies that did not approach murine models with the digestive form of the disease or did not use neuroprotective treatments, among others. The search in the PubMed, Web of Science, Embase, and LILACS databases was performed on September 4, 2021. In addition, a manual search was performed using the references of the included articles. The risk of bias assessment of the studies was performed based on the SYRCLE tool guidelines, and the data from the selected articles are presented in this review as a narrative description and in tables. Eight articles were included, 4 of which addressed treatment with acetylsalicylic acid, 3 with cyclophosphamide, and 1 with Lycopodium clavatum 13c. In view of the results of the studies, most of them show neuroprotective activity of the treatments, with the potential to reduce the number of damaged neurons, as well as positive changes in the structure of these cells. However, more studies are needed to understand the mechanisms triggered by each drug, as well as their safety and immunogenicity. Systematic review registration is as follows: PROSPERO database (CRD42022289746).

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Calomys callosus: An Experimental Animal Model Applied to Parasitic Diseases Investigations of Public Health Concern

Cited by 4 publications

References 85 publications

The trophoblast giant cells of cricetid rodents

The trophoblast giant cells of cricetid rodents

Phylogenetic and biogeographical traits predict unrecognized hosts of zoonotic leishmaniasis

Neuroprotective Treatments for Digestive Forms of Chagas Disease in Experimental Models: A Systematic Review

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