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PloS One 2022Parasite species richness is influenced by a range of drivers including host related factors (e.g. host size) and environmental factors (e.g. seawater temperature)....
Parasite species richness is influenced by a range of drivers including host related factors (e.g. host size) and environmental factors (e.g. seawater temperature). However, identification of modulators of parasite species richness remains one of the great unanswered questions in ecology. The common cockle Cerastoderma edule is renowned for its diversity and abundance of parasites, yet drivers of parasite species richness in cockles have not been examined to investigate the association of both macro and microparasite communities. Using cockles as a model species, some of the key drivers of parasite prevalence and parasite species richness were investigated. Objectives of this 19-month survey were to determine the influence of the environment, host-parasite dynamics and parasite associations on parasite species richness and prevalence at two different geographic latitudes, chosen based on environmental differences. The highest parasite species richness was recorded in the northern sites, and this was potentially influenced by a range of interactions between the host, the pathogens and the environment. Parasite prevalence increased with host size and age, and parasite species richness increased with reduced salinity. A number of interactions between parasites, and between parasites and pathologies may be influencing parasite infection dynamics. New and concerning information is also presented regarding interactions between parasites and their environment. A number of parasites and potential pathogens (bacteria, Trichodina ciliates, metacercariae, trematode sporocysts) may be advantaged under climate change conditions (warming seas, increased precipitation), increasing disease incidence, which may prove detrimental not just for cockles, but for other bivalve species in the future.
Topics: Animals; Cardiidae; Host-Parasite Interactions; Parasites; Prevalence; Trematoda
PubMed: 36155981
DOI: 10.1371/journal.pone.0274474 -
Philosophical Transactions of the Royal... Mar 2023As a result of global change, hosts and parasites (including pathogens) are experiencing shifts in their thermal environment. Despite the importance of heat stress... (Review)
Review
As a result of global change, hosts and parasites (including pathogens) are experiencing shifts in their thermal environment. Despite the importance of heat stress tolerance for host population persistence, infection by parasites can impair a host's ability to cope with heat. Host-parasite eco-evolutionary dynamics will be affected if infection reduces host performance during heating. Theory predicts that within-host parasite burden (replication rate or number of infecting parasites per host), a key component of parasite fitness, should correlate positively with virulence-the harm caused to hosts during infection. Surprisingly, however, the relationship between within-host parasite burden and virulence during heating is often weak. Here, we describe the current evidence for the link between within-host parasite burden and host heat stress tolerance. We consider the biology of host-parasite systems that may explain the weak or absent link between these two important host and parasite traits during hot conditions. The processes that mediate the relationship between parasite burden and host fitness will be fundamental in ecological and evolutionary responses of host and parasites in a warming world. This article is part of the theme issue 'Infectious disease ecology and evolution in a changing world'.
Topics: Animals; Host-Parasite Interactions; Virulence; Parasites; Phenotype; Heat-Shock Response; Biological Evolution
PubMed: 36744570
DOI: 10.1098/rstb.2022.0018 -
Frontiers in Immunology 2021
Topics: Animals; Disease Susceptibility; Host-Parasite Interactions; Humans; Nerve Tissue; Organ Specificity; Parasites; Tropism
PubMed: 34659274
DOI: 10.3389/fimmu.2021.775666 -
Acta Tropica Aug 2019Parasites use excretory-secretory pathways to communicate with the host. Characterization of exosomes within the excretory-secretory products reveal by which parasites... (Review)
Review
Parasites use excretory-secretory pathways to communicate with the host. Characterization of exosomes within the excretory-secretory products reveal by which parasites manipulate their hosts. Parasite derived exosomes provide a mechanistic framework for protein and miRNAs transfer. Transcriptomics and proteomics of parasite exosomes identified a large number of miRNAs and proteins being utilized by parasites in their survival, reproduction and development. Characterization of proteins and miRNAs in parasite secreted exosomes provide important information on host-parasite communication and forms the basis for future studies. In this review, we summarize recent advances in isolation and molecular characterization (protein and miRNAs) of parasite derived exosomes.
Topics: Animals; Exosomes; MicroRNAs; Parasites; Proteins; Proteomics; Transcriptome
PubMed: 31071298
DOI: 10.1016/j.actatropica.2019.05.004 -
Infection, Genetics and Evolution :... Jun 2022Because parasite data reveal essential information about the behavior and history of their hosts, it is possible to use them as tracers of host evolution. A table built...
Because parasite data reveal essential information about the behavior and history of their hosts, it is possible to use them as tracers of host evolution. A table built from the analysis of the data contained in the book by Ashford and Crewe "The Parasites of Homo sapiens" allows counting and cross comparing the parasites according to the main descriptors used by the authors: Taxonomic groups, for each group number of parasites species identified in humans; Status, numbers of reported human cases and their dispersion; Geographic distribution, parasite specific richness recorded in biogeographic regions; Habitat, parasite location in or on the human body; Transmission, contamination pathways to man; Hosts, non-human hosts, which have a role in the maintenance of a parasite; Host-specificity status, relative role of man or other hosts in the maintenance of parasite populations. A strong positive correlation is observed between the number of parasites species recorded in humans and the global parasite species richness for each taxonomic group. About 74% of the parasites recorded in humans are rare, sporadic or nowhere common; 10% only are common or abundant worldwide. The Palearctic exhibits the highest parasite species diversity; the Oriental, Nearctic, Neotropical and Aethiopian regions have roughly similar richness values; the Australian Region is the poorest. Earliest domesticated animals, such as dog, cat, cattle or pig, share more parasite species with Humans than tardily domesticated as horse, rabbit or camel. More than one third of our parasites have elected our alimentary canal as a home and about two third are using the digestive tract path for contamination. Time of occupancy of new territories, diversity in feeding habits and commensalism with other animals, widely explain Human particular parasite richness. As suggested by the authors: "There must be few parasitic species which have never had the opportunity to infect a human".
Topics: Animals; Australia; Cattle; Dogs; Ecosystem; Horses; Host Specificity; Host-Parasite Interactions; Humans; Parasites; Rabbits; Swine
PubMed: 35245684
DOI: 10.1016/j.meegid.2022.105262 -
Frontiers in Cellular and Infection... 2023Parasitic diseases pose a significant threat to global public health, particularly in developing countries. Host genetic factors play a crucial role in determining... (Review)
Review
Parasitic diseases pose a significant threat to global public health, particularly in developing countries. Host genetic factors play a crucial role in determining susceptibility and resistance to infection. Recent advances in molecular and biological technologies have enabled significant breakthroughs in understanding the impact of host genes on parasite adaptation. In this comprehensive review, we analyze the host genetic factors that influence parasite adaptation, including hormones, nitric oxide, immune cells, cytokine gene polymorphisms, parasite-specific receptors, and metabolites. We also establish an interactive network to better illustrate the complex relationship between host genetic factors and parasite-host adaptation. Additionally, we discuss future directions and collaborative research priorities in the parasite-host adaptation field, including investigating the impact of host genes on the microbiome, developing more sophisticated models, identifying and characterizing parasite-specific receptors, utilizing patient-derived sera as diagnostic and therapeutic tools, and developing novel treatments and management strategies targeting specific host genetic factors. This review highlights the need for a comprehensive and systematic approach to investigating the underlying mechanisms of parasite-host adaptation, which requires interdisciplinary collaborations among biologists, geneticists, immunologists, and clinicians. By deepening our understanding of the complex interactions between host genetics and parasite adaptation, we can develop more effective and targeted interventions to prevent and treat parasitic diseases. Overall, this review provides a valuable resource for researchers and clinicians working in the parasitology field and offers insights into the future directions of this critical research area.
Topics: Humans; Animals; Parasites; Host Adaptation; Cytokines; Microbiota; Nitric Oxide
PubMed: 37637465
DOI: 10.3389/fcimb.2023.1228206 -
Trends in Parasitology Jun 2022The capacity of malaria parasites to respond to changes in their environment at the transcriptional level has been the subject of debate, but recent evidence has... (Review)
Review
The capacity of malaria parasites to respond to changes in their environment at the transcriptional level has been the subject of debate, but recent evidence has unambiguously demonstrated that Plasmodium spp. can produce adaptive transcriptional responses when exposed to some specific types of stress. These include metabolic conditions and febrile temperature. The Plasmodium falciparum protective response to thermal stress is similar to the response in other organisms, but it is regulated by a transcription factor evolutionarily unrelated to the conserved transcription factor that drives the heat shock (HS) response in most eukaryotes. Of the many genes that change expression during HS, only a subset constitutes an authentic response that contributes to parasite survival.
Topics: Animals; Malaria; Malaria, Falciparum; Parasites; Plasmodium falciparum; Protozoan Proteins; Transcription Factors
PubMed: 35301987
DOI: 10.1016/j.pt.2022.02.009 -
Nature Communications Nov 2023Microbial eukaryotes are important components of marine ecosystems, and the Marine Alveolates (MALVs) are consistently both abundant and diverse in global environmental...
Microbial eukaryotes are important components of marine ecosystems, and the Marine Alveolates (MALVs) are consistently both abundant and diverse in global environmental sequencing surveys. MALVs are dinoflagellates that are thought to be parasites of other protists and animals, but the lack of data beyond ribosomal RNA gene sequences from all but a few described species means much of their biology and evolution remain unknown. Using single-cell transcriptomes from several MALVs and their free-living relatives, we show that MALVs evolved independently from two distinct, free-living ancestors and that their parasitism evolved in parallel. Phylogenomics shows one subgroup (MALV-II and -IV, or Syndiniales) is related to a novel lineage of free-living, eukaryovorous predators, the eleftherids, while the other (MALV-I, or Ichthyodinida) is related to the free-living predator Oxyrrhis and retains proteins targeted to a non-photosynthetic plastid. Reconstructing the evolution of photosynthesis, plastids, and parasitism in early-diverging dinoflagellates shows a number of parallels with the evolution of their apicomplexan sisters. In both groups, similar forms of parasitism evolved multiple times and photosynthesis was lost many times. By contrast, complete loss of the plastid organelle is infrequent and, when this does happen, leaves no residual genes.
Topics: Animals; Parasites; Ecosystem; Phylogeny; Plastids; Photosynthesis; Dinoflagellida
PubMed: 37923716
DOI: 10.1038/s41467-023-42807-0 -
How colonization bottlenecks, tissue niches, and transmission strategies shape protozoan infections.Trends in Parasitology Dec 2023Protozoan pathogens such as Plasmodium spp., Leishmania spp., Toxoplasma gondii, and Trypanosoma spp. are often associated with high-mortality, acute and chronic... (Review)
Review
Protozoan pathogens such as Plasmodium spp., Leishmania spp., Toxoplasma gondii, and Trypanosoma spp. are often associated with high-mortality, acute and chronic diseases of global health concern. For transmission and immune evasion, protozoans have evolved diverse strategies to interact with a range of host tissue environments. These interactions are linked to disease pathology, yet our understanding of the association between parasite colonization and host homeostatic disruption is limited. Recently developed techniques for cellular barcoding have the potential to uncover the biology regulating parasite transmission, dissemination, and the stability of infection. Understanding bottlenecks to infection and the in vivo tissue niches that facilitate chronic infection and spread has the potential to reveal new aspects of parasite biology.
Topics: Animals; Humans; Host-Parasite Interactions; Protozoan Infections; Parasites; Toxoplasma; Plasmodium
PubMed: 37839913
DOI: 10.1016/j.pt.2023.09.017 -
Trends in Parasitology Feb 2020Organoids are multicellular culture systems that replicate tissue architecture and function, and are increasingly used as models of viral, bacterial, and protozoan... (Review)
Review
Organoids are multicellular culture systems that replicate tissue architecture and function, and are increasingly used as models of viral, bacterial, and protozoan infections. Organoids have great potential to improve our current understanding of helminth interactions with their hosts and to replace or reduce the dependence on using animal models. In this review, we discuss the applicability of this technology to helminth infection research, including strategies of co-culture of helminths or their products with organoids and the challenges, advantages, and drawbacks of the use of organoids for these studies. We also explore how complementing organoid systems with other cell types and components may allow more complex models to be generated in the future to further investigate helminth-host interactions.
Topics: Animals; Helminthiasis; Helminths; Humans; Organoids; Parasitology; Research
PubMed: 31791691
DOI: 10.1016/j.pt.2019.10.013