Case Report: The impact of severe cryptosporidiosis on the gut microbiota of a pediatric patient with CD40L immunodeficiency

Cryptosporidium parvum is a protozoan parasite and one of the leading causes of gastroenteritis in the world, primarily affecting very young children and immunocompromised patients. While infection is usually self-limiting, it can become chronic and even lethal in these vulnerable populations, in whom Cryptosporidium treatments are generally ineffective, due to their acting in concert with a functioning immune system. Here, we describe a case of chronic cryptosporidiosis in a European child with severe CD40L immunodeficiency infected with Cryptosporidium parvum of the IIa20G1 subgenotype, a lineage which has thus far only ever been described in the Middle East. After years of on-off treatment with conventional and non-conventional anti-parasitic drugs failed to clear parasitosis, we performed targeted metagenomics to observe the bacterial composition of the patient’s gut microbiota (GM), and to evaluate fecal microbiota transplantation (FMT) as a potential treatment option. We found that C. parvum infection led to significant shifts in GM bacterial composition in our patient, with consequent shifts in predicted intestinal functional signatures consistent with a state of persistent inflammation. This, combined with the patient’s poor prognosis and increasing parasitic burden despite many rounds of anti-parasitic drug treatments, made the patient a potential candidate for an experimental FMT procedure. Unfortunately, given the many comorbidities that were precipitated by the patient’s immunodeficiency and chronic C. parvum infection, FMT was postponed in favor of more urgently necessary liver and bone marrow transplants. Tragically, after the first liver transplant failed, the patient lost his life before undergoing FMT and a second liver transplant. With this case report, we present the first description of how cryptosporidiosis can shape the gut microbiota of a pediatric patient with severe immunodeficiency. Finally, we discuss how both our results and the current scientific literature suggest that GM modulations, either by probiotics or FMT, can become novel treatment options for chronic Cryptosporidium infection and its consequent complications, especially in those patients who do not respond to the currently available anti-parasitic therapies.

[1]  L. Sibley,et al.  Microbiota-produced indole metabolites disrupt mitochondrial function and inhibit Cryptosporidium parvum growth , 2023, Cell reports.

[2]  Zhengli Wang,et al.  Changes of gut microbiota and tricarboxylic acid metabolites may be helpful in early diagnosis of necrotizing enterocolitis: A pilot study , 2023, Frontiers in Microbiology.

[3]  K. Sonoyama,et al.  Administration of Bifidobacterium pseudolongum suppresses the increase of colonic serotonin and alleviates symptoms in dextran sodium sulfate-induced colitis in mice , 2023, Bioscience of microbiota, food and health.

[4]  W. Witola,et al.  Past, current, and potential treatments for cryptosporidiosis in humans and farm animals: A comprehensive review , 2023, Frontiers in Cellular and Infection Microbiology.

[5]  Yuyue Liu,et al.  The role of Akkermansia muciniphila in inflammatory bowel disease: Current knowledge and perspectives , 2023, Frontiers in Immunology.

[6]  Yankai Chang,et al.  Microbiome-Metabolomics Analysis of the Impacts of Cryptosporidium muris Infection in BALB/C Mice , 2022, Microbiology spectrum.

[7]  L. Putignani,et al.  How Modulations of the Gut Microbiota May Help in Preventing or Treating Parasitic Diseases , 2022, Current Tropical Medicine Reports.

[8]  M. Ali,et al.  Cryptosporidium infection induced the dropping of SCFAS and dysbiosis in intestinal microbiome of Tibetan pigs. , 2022, Microbial pathogenesis.

[9]  O. Stine,et al.  Akkermansia muciniphila Associated with Improved Linear Growth among Young Children, Democratic Republic of the Congo , 2022, Emerging infectious diseases.

[10]  Z. Bhutta,et al.  Gut Fungal Microbiome Responses to Natural Cryptosporidium Infection in Horses , 2022, Frontiers in Microbiology.

[11]  Oihane E. Albóniga,et al.  A Comprehensive Metabolomics Analysis of Fecal Samples from Advanced Adenoma and Colorectal Cancer Patients , 2022, Metabolites.

[12]  L. Putignani,et al.  Cryptosporidium: Still Open Scenarios , 2022, Pathogens.

[13]  A. Gasbarrini,et al.  How the gut parasitome affects human health , 2022, Therapeutic advances in gastroenterology.

[14]  L. Putignani,et al.  Clinical Parasitology and Parasitome Maps as Old and New Tools to Improve Clinical Microbiomics , 2021, Pathogens.

[15]  Wenjun Liu,et al.  Synergistic Effects of the Jackfruit Seed Sourced Resistant Starch and Bifidobacterium pseudolongum subsp. globosum on Suppression of Hyperlipidemia in Mice , 2021, Foods.

[16]  R. Sleator,et al.  A novel genotyping method for Cryptosporidium hominis. , 2021, Experimental parasitology.

[17]  A. Mackiewicz,et al.  Secretory IgA in Intestinal Mucosal Secretions as an Adaptive Barrier against Microbial Cells , 2020, International journal of molecular sciences.

[18]  A. Cabezas-Cruz,et al.  Cryptosporidium parvum Infection Depletes Butyrate Producer Bacteria in Goat Kid Microbiome , 2020, Frontiers in Microbiology.

[19]  Jason A. Papin,et al.  Megasphaera in the Stool Microbiota Is Negatively Associated With Diarrheal Cryptosporidiosis , 2020, bioRxiv.

[20]  A. Franke,et al.  Intestinal protozoan infections shape fecal bacterial microbiota in children from Guinea-Bissau , 2020, PLoS neglected tropical diseases.

[21]  M. Goldberg,et al.  Microbiota-Sourced Purines Support Wound Healing and Mucous Barrier Function , 2020, iScience.

[22]  Brandy E. Wade,et al.  Changes in the Microbiome of Cryptosporidium-Infected Mice Correlate to Differences in Susceptibility and Infection Levels , 2020, Microorganisms.

[23]  B. Slatko,et al.  Impact of intestinal parasites on microbiota and cobalamin gene sequences: a pilot study , 2020, Parasites & Vectors.

[24]  R. Baldassano,et al.  Natural Infection with Giardia Is Associated with Altered Community Structure of the Human and Canine Gut Microbiome , 2020, mSphere.

[25]  C. Biondo,et al.  Cryptosporidium Infection: Epidemiology, Pathogenesis, and Differential Diagnosis , 2019, European journal of microbiology & immunology.

[26]  G. Widmer,et al.  Deprivation of dietary fiber enhances susceptibility of mice to cryptosporidiosis , 2019, bioRxiv.

[27]  Ting Zhang,et al.  Akkermansia muciniphila is a promising probiotic , 2019, Microbial biotechnology.

[28]  G. García-Montoya,et al.  Intestinal parasitic infection alters bacterial gut microbiota in children , 2019, PeerJ.

[29]  Wei Chen,et al.  A next generation probiotic, Akkermansia muciniphila , 2018, Critical reviews in food science and nutrition.

[30]  G. Widmer,et al.  Probiotic Product Enhances Susceptibility of Mice to Cryptosporidiosis , 2018, Applied and Environmental Microbiology.

[31]  A. Gasbarrini,et al.  Hepatocellular Carcinoma Is Associated With Gut Microbiota Profile and Inflammation in Nonalcoholic Fatty Liver Disease , 2018, Hepatology.

[32]  G. Silecchia,et al.  Gut Microbiota Markers in Obese Adolescent and Adult Patients: Age-Dependent Differential Patterns , 2018, Front. Microbiol..

[33]  P. Hunter,et al.  Risk factors for Cryptosporidium infection in low and middle income countries: A systematic review and meta-analysis , 2018, PLoS neglected tropical diseases.

[34]  A. Graham,et al.  Parasite-Microbiota Interactions With the Vertebrate Gut: Synthesis Through an Ecological Lens , 2018, Front. Microbiol..

[35]  Lihua Xiao,et al.  Epidemiological observations on cryptosporidiosis and molecular characterization of Cryptosporidium spp. in sheep and goats in Kuwait , 2018, Parasitology Research.

[36]  Kongming Wu,et al.  Gut microbiome modulates efficacy of immune checkpoint inhibitors , 2018, Journal of Hematology & Oncology.

[37]  Boris Striepen,et al.  Cryptosporidium , 2018, Current Biology.

[38]  B. Dallapiccola,et al.  “Omic” investigations of protozoa and worms for a deeper understanding of the human gut “parasitome” , 2017, PLoS neglected tropical diseases.

[39]  E. Mongodin,et al.  Complete Genome Sequence of a Strain of Bifidobacterium pseudolongum Isolated from Mouse Feces and Associated with Improved Organ Transplant Outcome , 2017, Genome Announcements.

[40]  J. M. Larsen The immune response to Prevotella bacteria in chronic inflammatory disease. , 2017, Immunology.

[41]  B. Lucey,et al.  Towards understanding clinical campylobacter infection and its transmission: time for a different approach? , 2017, British journal of biomedical science.

[42]  R. Mukbel,et al.  Genetic characterization of Cryptosporidium in animal and human isolates from Jordan. , 2016, Veterinary parasitology.

[43]  R. Chalmers,et al.  Human cryptosporidiosis in Europe. , 2016, Clinical microbiology and infection : the official publication of the European Society of Clinical Microbiology and Infectious Diseases.

[44]  M. Santín,et al.  Effects of Enterococcus faecalis CECT 7121 on Cryptosporidium parvum infection in mice , 2016, Parasitology Research.

[45]  R. Haque,et al.  Role of the Gut Microbiota of Children in Diarrhea Due to the Protozoan Parasite Entamoeba histolytica , 2015, The Journal of infectious diseases.

[46]  A. Simoes-Barbosa,et al.  The Interplay of Host Microbiota and Parasitic Protozoans at Mucosal Interfaces: Implications for the Outcomes of Infections and Diseases , 2015, PLoS neglected tropical diseases.

[47]  H. Nielsen,et al.  A retrospective metagenomics approach to studying Blastocystis. , 2015, FEMS microbiology ecology.

[48]  G. Kang,et al.  Immune response and intestinal permeability in children with acute gastroenteritis treated with Lactobacillus rhamnosus GG: a randomized, double-blind, placebo-controlled trial. , 2014, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[49]  Karen L. Kotloff,et al.  Burden of disease from cryptosporidiosis , 2012, Current opinion in infectious diseases.

[50]  R. Trengove,et al.  Development of an untargeted metabolomics method for the analysis of human faecal samples using Cryptosporidium-infected samples. , 2012, Molecular and biochemical parasitology.

[51]  F. Callea,et al.  Cases of cryptosporidiosis co-infections in AIDS patients: a correlation between clinical presentation and GP60 subgenotype lineages from aged formalin-fixed stool samples , 2011, Annals of tropical medicine and parasitology.

[52]  M. Zali,et al.  Subtype analysis of Cryptosporidium parvum and Cryptosporidium hominis isolates from humans and cattle in Iran. , 2011, Veterinary parasitology.

[53]  M. Widdowson,et al.  Foodborne Illness Acquired in the United States—Major Pathogens , 2011, Emerging infectious diseases.

[54]  C. Subauste CD40 and the immune response to parasitic infections. , 2009, Seminars in immunology.

[55]  I. Sulaiman,et al.  Unique Endemicity of Cryptosporidiosis in Children in Kuwait , 2005, Journal of Clinical Microbiology.

[56]  N. Pickerd,et al.  Resolution of cryptosporidiosis with probiotic treatment , 2004, Postgraduate Medical Journal.

[57]  A. Hayward,et al.  Marrow-Derived CD40-Positive Cells Are Required for Mice To Clear Cryptosporidium parvum Infection , 2001, Infection and Immunity.

[58]  H. Dupont,et al.  Fecal Antibodies to Cryptosporidium parvum in Healthy Volunteers , 2000, Infection and Immunity.

[59]  R. Flavell,et al.  Requirement for CD40-CD40 Ligand Interaction for Elimination of Cryptosporidium parvum from Mice , 1998, Infection and Immunity.

[60]  M. O'gorman,et al.  Development of a rapid whole blood flow cytometry procedure for the diagnosis of X-linked hyper-IgM syndrome patients and carriers. , 1997, Clinical immunology and immunopathology.

[61]  L. Notarangelo,et al.  Cholangiopathy and tumors of the pancreas, liver, and biliary tree in boys with X-linked immunodeficiency with hyper-IgM. , 1997, Journal of immunology.

[62]  M. Mir Introduction to Costimulation and Costimulatory Molecules , 2015 .

[63]  Mark A. Miller,et al.  A review of the global burden, novel diagnostics, therapeutics, and vaccine targets for cryptosporidium. , 2015, The Lancet. Infectious diseases.

[64]  O. Adeyemo,et al.  Effect of Lactobacillus reuteri on intestinal resistance to Cryptosporidium parvum infection in a murine model of acquired immunodeficiency syndrome. , 1997, The Journal of infectious diseases.