How to become a top model: impact of animal experimentation on human Salmonella disease research.
about
Salmonella pathogenicity and host adaptation in chicken-associated serovarsReplication of Salmonella enterica Serovar Typhimurium in Human Monocyte-Derived MacrophagesSalmonella uses energy taxis to benefit from intestinal inflammationCD11b+ Ly6Chi Ly6G- immature myeloid cells recruited in response to Salmonella enterica serovar Typhimurium infection exhibit protective and immunosuppressive properties.Salmonella enterica serovar Typhi impairs CD4 T cell responses by reducing antigen availabilityImmunity to intestinal pathogens: lessons learned from SalmonellaThe transcriptional landscape and small RNAs of Salmonella enterica serovar Typhimurium.Immunity to intracellular Salmonella depends on surface-associated antigens.Parallel exploitation of diverse host nutrients enhances Salmonella virulence.Novel determinants of intestinal colonization of Salmonella enterica serotype typhimurium identified in bovine enteric infection.Salmonella enterica infection stimulates macrophages to hemophagocytoseFine-mapping and phenotypic analysis of the Ity3 Salmonella susceptibility locus identify a complex genetic structure.Interaction of Salmonella spp. with the Intestinal MicrobiotaPersistent salmonellosis causes pancreatitis in a murine model of infectionL-asparaginase II produced by Salmonella typhimurium inhibits T cell responses and mediates virulence.Salmonella Typhimurium strain ATCC14028 requires H2-hydrogenases for growth in the gut, but not at systemic sites.Increased ferroportin-1 expression and rapid splenic iron loss occur with anemia caused by Salmonella enterica Serovar Typhimurium infection in miceOral Wild-Type Salmonella Typhi Challenge Induces Activation of Circulating Monocytes and Dendritic Cells in Individuals Who Develop Typhoid Disease.Salmonella, the host and its microbiota.Inflammation-associated alterations to the intestinal microbiota reduce colonization resistance against non-typhoidal Salmonella during concurrent malaria parasite infection.Physiologic Stresses Reveal a Salmonella Persister State and TA Family Toxins Modulate Tolerance to These Stresses.A glycine betaine importer limits Salmonella stress resistance and tissue colonization by reducing trehalose productionA multi-drug resistant Salmonella Typhimurium ST213 human-invasive strain (33676) containing the bla CMY-2 gene on an IncF plasmid is attenuated for virulence in BALB/c mice.Bacterial Stimulation of Toll-Like Receptor 4 Drives Macrophages To Hemophagocytose.Single passage in mouse organs enhances the survival and spread of Salmonella entericaCutting edge: B cells are essential for protective immunity against Salmonella independent of antibody secretion.Asparagine deprivation mediated by Salmonella asparaginase causes suppression of activation-induced T cell metabolic reprogramming.Genome expression analysis of nonproliferating intracellular Salmonella enterica serovar Typhimurium unravels an acid pH-dependent PhoP-PhoQ response essential for dormancy.Loss of very-long O-antigen chains optimizes capsule-mediated immune evasion by Salmonella enterica serovar Typhi.Energy Taxis toward Host-Derived Nitrate Supports a Salmonella Pathogenicity Island 1-Independent Mechanism of Invasion.Salmonella enterica causes more severe inflammatory disease in C57/BL6 Nramp1G169 mice than Sv129S6 mice.Malaria-associated L-arginine deficiency induces mast cell-associated disruption to intestinal barrier defenses against nontyphoidal Salmonella bacteremiaSalmonella Infection Enhances Erythropoietin Production by the Kidney and Liver, Which Correlates with Elevated Bacterial BurdensSalmonella Extracellular Matrix Components Influence Biofilm Formation and Gallbladder Colonization.Contribution of Asparagine Catabolism to Salmonella Virulence.The IL-23 axis in Salmonella gastroenteritis.Molecular phenotyping of infection-associated small non-coding RNAs.Myeloperoxidase targets oxidative host attacks to Salmonella and prevents collateral tissue damage.Evaluation of nisin-β-lactam antibiotics against clinical strains of Salmonella enterica serovar Typhi.Bile Acid Administration Elicits an Intestinal Antimicrobial Program and Reduces the Bacterial Burden in Two Mouse Models of Enteric Infection.
P2860
Q26999425-95589DC9-FCFF-4C83-B5B8-1B71CFC248A7Q27322789-507442E1-C749-4C0E-8A6C-B1F1D6206B63Q27335357-857968CB-4595-4806-9ACA-A1EC9B569C3FQ33603022-A8D19E3F-8F11-4E3C-8F4A-598B57DF7538Q33603033-FBB35AA7-2AC7-4E65-91DF-6EA210829B1BQ33788711-37F3E3BC-E78B-418C-868F-8CAB9B4A9B8CQ34248983-4C2E11D3-1803-4B6E-8BC5-D72877FFEF93Q34456080-07447F01-89E1-4276-93FA-5C7F50DAB1ECQ34697874-DD0FB3AC-DA19-4A3F-8404-4F747D1AB299Q34982542-9783E033-2B35-421C-99D7-98C62E45912DQ35072142-B19EA8B7-F4B4-4B0F-842C-199D19C6EFA7Q35088379-2361720B-D314-4A92-B43D-29ABD045D303Q35090110-7B3DBAE1-CA71-4969-A521-212F4A7D8085Q35143668-8F949EF0-B48C-4D9D-B331-030C383C2ED9Q35180579-094D6AD9-5F0F-4866-95C0-D477CE4749B3Q35321261-D26109FE-80AE-4F1C-BE17-329BB5DCBF28Q35609338-4B4CA6DA-C010-4546-9A8B-3EEA4DEA8FD1Q35660952-65D34E81-2216-4EC0-9BE4-036A3DAFFA9EQ35693313-26DC73A5-C850-4556-9B1F-6E0996E9542EQ35798458-4E74F17E-4C81-44D8-977E-8FA4C80295E5Q35859948-6E977F20-0743-41D1-BEDB-E26FA432D1F2Q35881567-84203FA9-81E7-4F8E-9F03-E62A8476744AQ35919194-7601245D-79B1-4E1B-ADC0-A28B9B234D41Q36410913-0A00E520-3642-4110-9947-0CDF1933B5D4Q36449778-7342DD31-29B5-49E8-9221-DD386C626221Q36456788-6E73FEE4-CFBE-43D6-9BFC-5C9B5DA78C71Q36477909-B185EA77-604B-47C0-8EFC-990075D91DABQ36506142-035CE95F-3A48-4B06-BDF3-0CDC904CC9C7Q37074488-355F6DF6-98B7-4596-A898-5C5B53600E52Q37120272-3BE29C2B-90B0-494D-A65E-37B10EA63446Q37161148-95451103-CD46-4B8C-B763-E27116E6C6B4Q37264637-061CF610-FE50-4B1B-A167-BED255AE62E6Q37287154-8258EF72-9E8A-4AEB-8EF9-A2A2BFAE475DQ37345933-1C12640A-B111-46EB-828B-3AE866B6470CQ37611979-E261AA59-6B16-4F5C-9D5C-5D4317888655Q37899273-7846983A-2ADD-4089-B365-6C21F1D86000Q38965426-39E6584B-A45A-4A49-A2D4-0739D3B90F33Q39005654-806E45EB-2A47-4EA6-BE4C-CBE4A8C2BAD9Q40202552-CB52FAE2-F971-4B4B-9026-DD28DAD6139AQ40276600-3ECFB16B-C68C-45B1-835F-D18D4D0A46E6
P2860
How to become a top model: impact of animal experimentation on human Salmonella disease research.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 22 February 2011
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
How to become a top model: imp ...... n Salmonella disease research.
@en
How to become a top model: imp ...... n Salmonella disease research.
@nl
type
label
How to become a top model: imp ...... n Salmonella disease research.
@en
How to become a top model: imp ...... n Salmonella disease research.
@nl
prefLabel
How to become a top model: imp ...... n Salmonella disease research.
@en
How to become a top model: imp ...... n Salmonella disease research.
@nl
P2860
P50
P356
P1476
How to become a top model: imp ...... an Salmonella disease research
@en
P2093
Andreas J Bäumler
P2860
P304
P356
10.1128/IAI.01369-10
P407
P577
2011-02-22T00:00:00Z