Brett Webb’s research while affiliated with University of Wyoming and other places

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Publications (26)


Marked Neurotropism and Potential Adaptation of H5N1 Clade 2.3.4.4.b Virus in Naturally Infected Domestic Cats
  • Article

December 2024

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30 Reads

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Sougat Misra

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In April 2024, ten cats died in a rural South Dakota (SD) residence, showing respiratory and neurological symptoms. Necropsy and laboratory testing of two cats confirmed H5N1 clade 2.3.4.4b infection. The viral genome sequences are closely related to recent SD cattle H5N1 sequences. Cat H5N1 genomes had unique mutations, including T143A in haemagglutinin, known to affect infectivity and immune evasion, and two novel mutations in PA protein (F314L, L342Q) that may affect polymerase activity and virulence, suggesting potential virus adaptation. Dead cats showed systemic infection with lesions and viral antigens in multiple organs. Higher viral RNA and antigen in the brain indicated pronounced neurotropism. Lectin-histochemistry revealed widespread co-expression of sialic acid α-2,6 and α-2,3 receptors, suggesting cats could serve as mixing vessels for reassortment of avian and mammalian influenza viruses. No differences in clade 2.2 or 2.3.4.4b H5 pseudoviruses binding to cat lung/brain tissues indicated the neurotropism is unlikely mediated by receptor binding affinity.


Experimental design to assess the impact of reinfection and secondary infection with SARS-CoV-2 in mice with different genetic backgrounds
Mice were first infected with either Mock (PBS), BA.1 (10⁴ PFU) or NC99 (10² PFU) and allowed to recover for 30 days (1st infection, highlighted in black). 7- and 30-days post infection (DPI), 5 animals from each group were necropsied and bronchioalveolar lavage fluid (BALF) was collected to evaluate CD11c+ populations via flow cytometry. At 30 DPI, BA.1- infected or mock-infected mice (n = 3) were euthanized to collect serum, whole lungs and BALF. Whole lungs were used for downstream analysis of T-cell responses by flow cytometry. Bronchioalveolar lavage fluid (BALF; n = 5) was the source of CD11c+ cells for isolation, which were further subjected to transcriptome and cytokine/chemokine recall response analysis. Serum collected at 30 DPI was used to assess antibody responses against BA.1 and B.1.351 spike protein and for further passive immunization studies (highlighted in blue). For T-cell depletion experiments, mice were depleted at 28 and 30 DPI (24 h and 72 h prior to B.1.351 challenge). 31 days after the first infection, mice were challenged with 10⁴ PFU of B.1.351 (2nd infection, highlighted in red). After the 2nd infection, mice’s bodyweights were measured daily to assess infection severity. 4 days after B.1.351 challenge (4DPI, highlighted in red), mice were necropsied and lungs were collected for downstream analysis of lung virus titers, lung histopathogy and cytokine/chemokine responses. For passive immunization experiments (highlighted in blue), 129S1 mice were intraperitoneal injected with pooled serum from either mock infected or BA.1 infected mice. One day after, mice were infected with B.1.351 (10⁴ PFU). Again, 4 days after B.1.351 infection, mice were necropsied and lungs were collected to assess viral titers, histopathogy and cytokine/chemokine responses. The number of mice/group used for the different analyses is mentioned in each figure legend. Created in BioRender. Singh (2022) https://BioRender.com/a23x374.
Opposite effects of BA.1 or NC99 pre-exposure in B.1.351 disease severity outcomes depending on mouse genetic background
K18-hACE2 or 129S1 mice were infected with B.1.351 31 days after exposure to BA.1 (reinfection, n = 5) or NC99 (secondary infection, n = 5). A group mock infected twice (Mock:Mock, n = 5) and a group mock-infected and challenged 31 days after with B.1.351 (Mock:B.1.351, n = 10) were also included. Samples from every mice were used for every analysis unless otherwise specified. A (i): Mean ± SD weight change in 129S1 mice after mock-challenge or challenge with 10⁴ PFU of B.1.351. Statistical analysis: Kruskal–Wallis test with Dunnett’s multiple comparisons test to the Mock:Mock group. A (ii): Infectious virus titers in the lungs of mock, BA.1 (n = 5) or NC99 pre-infected (n = 3) 129S1 mice inoculated with 10⁴ PFU of B.1.351. Representation: Box-plot with median as center, 25th to 75th percentile-bound box and whiskers representing maximum and minimum values. Statistical analysis: Ordinary two-way ANOVA with Dunnett’s multiple comparisons test to the Mock:Mock group. A (iii): Histopathological scores from mock or BA.1 pre-infected 129S1 mice inoculated with mock or 10⁴ PFU of B.1.351 (n = 5, per group). B (i): Mean±SD weight change in K18-hACE2 mice after mock-challenge or challenge with 10⁴ PFU of B.1.351. Statistical analysis: see A (i). B (ii): Infectious virus titer in lungs of mock or BA.1 or NC99 pre-infected K18-hACE2 mice inoculated with mock or 10⁴ PFU of B.1.351. Representation and statistical analysis: see A (ii). B (iii): Histopathological scores from mock or BA.1 pre-infected K18-hACE2 mice inoculated with mock or 10⁴ PFU of B.1.351 (n = 5, per group). C: Heatmap of cytokine/chemokine profile of lung homogenates from mock, BA.1 or NC99 pre-infected K18-hACE2 or 129S1 mice inoculated with mock or 10⁴ PFU of B.1.351. Z-score calculations from average Net-MFI results are represented. D: EGFR protein quantification from lung homogenates from BA.1 pre-infected K18-hACE2 (n = 5) or 129S1 (n = 5) mice or mock pre-infected [K18-hACE2 (n = 4) or 129S1 (n = 5)] mice challenged with 10⁴ PFU of B.1.351. Representation: see A (ii). Statistical analysis: Two-tailed Mann–Whitney T-test. Statistical significance is represented as exact p-value. Source data are provided as a Source Data file.
Differences in adaptive immune responses upon BA.1 infection do not explain differences in re-infection outcomes
A Line graph showing ELISA results in transformed Log2 fold dilutions (x-axis) of 30 DPI serum from K18-hACE2 (n = 4) and 129S1 (n = 5) versus mean ±SD OD values at 450 nm (y-axis) against B.1.351 spike (i) or BA.1 spike (ii) protein. B (i): Mean ±SD weight change in 129S1 mice inoculated with 10⁴ PFU of B.1.351 after passive immunization with either mock (n = 5) or ant-BA.1 serum (n = 5). B (ii): Infectious virus titers in lungs from passive immunized 129S1 mice with either mock (n = 5) or ant-BA.1 serum (n = 5) 4 DPI after B.1.351 inoculation. Representation: Box-plot with median as center, 25th to 75th percentile-bound box and whiskers representing maximum and minimum values. Statistical analysis: Two-tailed Mann–Whitney T-test. C (i): Spike-specific T-cells as percentage (mean±SD) of total T cells in murine lungs at 30 DPI after BA.1 or mock challenge (129S1 mice n = 4 per group, K18-hACE2 mice n = 3 per group). C (ii): Spike-specific tissue resident memory T-cells as percentage (mean±SD) of total T cells in murine lungs at 30 DPI after BA.1 or mock challenge (129S1 mice n = 4 per group, K18-hACE2 mice n = 3 per group). D: B.1.351 lung viral titers 4 DPI in 129S1 mice pre-exposed or not to BA.1, either T-cell depleted or immunocompetent (n = 5, per group). Representation: see B(ii), E Heatmap graph of cytokine/chemokine profile of lung homogenates from mock or BA.1 pre-infected 129S1 mice, either T-cell depleted or not, inoculated with either 10⁴ PFU of B.1.351. Z-score calculations from Net-MFI results are represented in the heatmap (n = 5, per group). Mann–Whitney t-test was used to determine statistical significance of the results, where exact p-values are presented. Source data are provided as a Source Data file.
CD11c+ alveolar compartment is extensively remodeled after BA.1 and NC99 infection
Early (7 DPI) and late (30 DPI) timepoints after NC99 or BA.1 infection reveal profound changes in the CD11c+ subpopulations of BALF. A Total number of CD11c+ cells (mean ± SD) in BALF collected from 129S1 mice 7- and 30-days post infection with Mock (n = 5 per timepoint), NC99 (n = 5 at 7DPI, n = 4 at 30DPI) or BA.1 (n = 5 per timepoint). B Total number of CD11c+ cells (mean ± SD) in BALF collected from K18-hACE2 mice 7DPI and 30 DPI with Mock (n = 5 per timepoint), NC99 (n = 5 per timepoint) or BA.1 (n = 5 at 7DPI, n = 30 at 30DPI). Statistical analysis by ordinary one-way ANOVA with Dunnett’s multiple comparison. C–G Dimensionality reduction analysis performed by Uniform Manifold Approximation and Projection with a Nearest-Neighbours clustering algorithm combined with FlowSOM cluster visualization algorithm. Data from mice in the sample group was combined and randomely downsampled to a total of 10.000 events per group prior to the analysis dimensionality reduction analysis. C Expression levels of CD11c+. Higher expression levels indicated by red colors; lower expression levels indicated by green colors. D CD11c+ subpopulation clusters in BALF collected from 129S1 animals either mock-, NC99- or BA.1-challenged, 7 or 30 DPI. E CD11c+ subpopulation clusters in BALF collected from K18-hACE2 animals either mock-, NC99- or BA.1-challenged, 7 or 30 DPI. F Heatmap of the expression of CD3, Ly6G, Ly6C, CD11b, B220, SiglecF, MHCII and CD11c markers in the different populations. G Stack bar plot with the frequencies of the different CD11c+ populations in 129S1 and K18-hACE2 mice, depending on the infection and the day of collection of the BALF. Experiments were performed with 5 or 4 mice per group and per timepoint. Source data are provided as a Source Data file.
CD11c+ cells react differently during ex vivo restimulation depending on mouse genetic background and prior exposure to BA.1 virus
BA.1 inoculated K18-hACE2 (n = 8) or 129S1 (n = 9) mice were euthanized after 30 DPI, Lungs (n = 4 or 3) or BALF (n = 5) were collected. CD11c+ cells were enriched from the BALF and used for trained immunity experiment. A Heatmap graph of the cytokine/chemokine profile of CD11c+ BALF cells either stimulated with mock media (1X RPMI, upper), Beta (10⁴ PFU of B.1.351, middle), or LPS (lower) after 48 h. B Results from the long-read-RNAseq analysis from CD11c+ BALF cells isolated from mice at 30 days post-infection. Sankey diagram selected gene with their relative gene expression in mock groups and their relative change after BA.1 infection in each strain. C Top 100 up and down regulated genes by BA.1 infection in CD11c+ cells from 129S1 and K18-hACE2 mice represented as Log2(Fold change). Source data are provided as a Source Data file.
Outcome of SARS-CoV-2 reinfection depends on genetic background in female mice
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  • Full-text available

November 2024

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35 Reads

Antigenically distinct SARS-CoV-2 variants increase the reinfection risk for vaccinated and previously exposed population due to antibody neutralization escape. COVID-19 severity depends on many variables, including host immune responses, which differ depending on genetic predisposition. To address this, we perform immune profiling of female mice with different genetic backgrounds –transgenic K18-hACE2 and wild-type 129S1– infected with the severe B.1.351, 30 days after exposure to the milder BA.1 or severe H1N1. Prior BA.1 infection protects against B.1.351-induced morbidity in K18-hACE2 but aggravates disease in 129S1. H1N1 protects against B.1.351-induced morbidity only in 129S1. Enhanced severity in B.1.351 re-infected 129S1 is characterized by an increase of IL-10, IL-1β, IL-18 and IFN-γ, while in K18-hACE2 the cytokine profile resembles naïve mice undergoing their first viral infection. Enhanced pathology during 129S1 reinfection cannot be attributed to weaker adaptive immune responses to BA.1. Infection with BA.1 causes long-term differential remodeling and transcriptional changes in the bronchioalveolar CD11c+ compartment. K18-hACE2 CD11c+ cells show a strong antiviral defense expression profile whereas 129S1 CD11c+ cells present a more pro-inflammatory response upon restimulation. In conclusion, BA.1 induces cross-reactive adaptive immune responses in K18-hACE2 and 129S1, but reinfection outcome correlates with differential CD11c+ cells responses in the alveolar space.

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Comparative evaluation of assay performance for SARS-CoV-2 detection in animal oral samples, lung homogenates, and phosphate-buffered saline using the TaqPath COVID-19 Combo kit

February 2024

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7 Reads

Journal of veterinary diagnostic investigation: official publication of the American Association of Veterinary Laboratory Diagnosticians, Inc

A One Health approach has been key to monitoring the COVID-19 pandemic, as human and veterinary medical professionals jointly met the demands for an extraordinary testing effort for SARS-CoV-2. Veterinary diagnostic laboratories continue to monitor SARS-CoV-2 infection in animals, furthering the understanding of zoonotic transmission dynamics between humans and animals. A RT-PCR assay is a primary animal screening tool established within validation and verification guidelines provided by the American Association of Veterinary Laboratory Diagnosticians (AAVLD), World Organisation for Animal Health (WOAH), and the U.S. Food and Drug Administration (FDA). However, differences in sample matrices, RNA extraction methods, instrument platforms, gene targets, and cutoff values may affect test outcomes. Therefore, targeted validation for a new sample matrix used in any PCR assay is critical. We evaluated a COVID-19 assay for the detection of SARS-CoV-2 in feline and canine lung homogenates and oral swab samples. We used the commercial Applied Biosystems MagMAX Viral/Pathogen II (MVP II) nucleic acid isolation kit and TaqPath COVID-19 Combo kit, which are validated for a variety of human samples, including nasopharyngeal and oropharyngeal swab samples. Our masked test showed a high detection rate and no false-positive or false-negative results, supporting sample extension to include feline oral swab samples. Our study is a prime example of One Health, illustrating how a COVID-19 assay designed for human testing can be adapted and used to detect SARS-CoV-2 in oral swab samples from cats and likely dogs, but not lung homogenates.


Trans-replicase helper activity of porcine circoviruses promotes the synergistic replication of torque teno virus

January 2024

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60 Reads

While the primary pathogenic potential of torque teno viruses (TTVs) is yet to be defined, TTVs are often co-detected with other pathogens and are suspected of exacerbating clinical disease in coinfections. Swine TTVs (TTSuVs) enhance clinical signs of porcine circovirus type 2 (PCV2) in a gnotobiotic pig model. However, the mechanisms involved are unknown. In this study, we observed that co-culture of TTSuV1 and PCV1, and specifically supplementing TTSuV1 cultures with the PCV replicase protein in trans consistently resulted in higher levels of replication of TTSuV1 when compared to TTSuV1 cultured alone. Therefore, the hypothesis that the PCV replicase (rep) protein has trans-replicase helper activity for TTSuV1 was examined. Based on EMSA and reporter gene assays, it was determined that the PCV1 rep directly interacted with the TTSuV1 UTR. The TTSuV1 rep trans-complemented a PCV rep null mutant virus, indicating that the TTSuV1 and PCV1 replicase proteins supported the replication of both viruses. In mice, the administration of plasmids encoding the PCV1 rep and a TTSuV1 infectious clone resulted in the production of higher TTSuV1 genome copies in dually exposed mice when compared to singly exposed mice. Higher sero-conversion and lymphoid hyperplasia were also observed in the dually exposed experimental mice. Thus, this study provides evidence for trans-replicase activity of PCVs and TTVs as a novel mechanism of explaining enhanced viral replication in coinfections involving both viruses.


Breakthrough infections by SARS-CoV-2 variants boost cross-reactive hybrid immune responses in mRNA-vaccinated Golden Syrian hamsters

January 2024

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52 Reads

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2 Citations

Hybrid immunity (vaccination + natural infection) to SARS-CoV-2 provides superior protection to re-infection. We performed immune profiling studies during breakthrough infections in mRNA-vaccinated hamsters to evaluate hybrid immunity induction. The mRNA vaccine, BNT162b2, was dosed to induce binding antibody titers against ancestral spike, but inefficient serum virus neutralization of ancestral SARS-CoV-2 or variants of concern (VoCs). Vaccination reduced morbidity and controlled lung virus titers for ancestral virus and Alpha but allowed breakthrough infections in Beta, Delta and Mu-challenged hamsters. Vaccination primed for T cell responses that were boosted by infection. Infection back-boosted neutralizing antibody responses against ancestral virus and VoCs. Hybrid immunity resulted in more cross-reactive sera, reflected by smaller antigenic cartography distances. Transcriptomics post-infection reflects both vaccination status and disease course and suggests a role for interstitial macrophages in vaccine-mediated protection. Therefore, protection by vaccination, even in the absence of high titers of neutralizing antibodies in the serum, correlates with recall of broadly reactive B- and T-cell responses.


Host immune responses associated with SARS-CoV-2 Omicron infection result in protection or pathology during reinfection depending on mouse genetic background

November 2023

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56 Reads

Rapid emergence of antigenic distinct SARS-CoV-2 variants implies a greater risk of reinfection as viruses can escape neutralizing antibodies induced by vaccination or previous viral exposure. Disease severity during COVID-19 depends on many variables such as age-related comorbidities, host immune status and genetic variation. The host immune response during infection with SARS-CoV-2 may contribute to disease severity, which can range from asymptomatic to severe with fatal outcome. Furthermore, the extent of host immune response activation may rely on underlying genetic predisposition for disease or protection. To address these questions, we performed immune profiling studies in mice with different genetic backgrounds - transgenic K18-hACE2 and wild-type 129S1 mice – subjected to reinfection with the severe disease-causing SARS-CoV-2 B.1.351 variant, 30 days after experimental milder BA.1 infection. BA.1 preinfection conferred protection against B.1.351-induced morbidity in K18-hACE2 mice but aggravated disease in 129S1 mice. We found that he cytokine/chemokine profile in B.1.351 re-infected 129S1mice is similar to that during severe SARS-CoV-2 infection in humans and is characterized by a much higher level of IL-10, IL-1β, IL-18 and IFN-γ, whereas in B.1.351 re-infected K18-hACE2 mice, the cytokine profile echoes the signature of naïve mice undergoing viral infection for the first time. Interestingly, the enhanced pathology observed in 129S1 mice upon reinfection cannot be attributed to a less efficient induction of adaptive immune responses to the initial BA.1 infection, as both K18-hACE2 and 129S1 mice exhibited similar B and T cell responses at 30 DPI against BA.1, with similar anti-BA.1 or B.1.351 spike-specific ELISA binding titers, levels of germinal center B-cells, and SARS-CoV-2-Spike specific tissue-resident T-cells. Long-term effects of BA.1 infection are associated with differential transcriptional changes in bronchoalveolar lavage-derived CD11c + immune cells from K18-hACE2 and 129S1, with K18-hACE2 CD11c + cells showing a strong antiviral defense gene expression profile whereas 129S1 CD11c + cells showed a more pro-inflammatory response. In conclusion, initial infection with BA.1 induces cross-reactive adaptive immune responses in both K18-hACE2 and 129S1 mice, however the different disease outcome of reinfection seems to be driven by differential responses of CD11c + cells in the alveolar space.


Visual presentation of ALD in a Rambouillet ram from UWY. The ram to the left demonstrates normal structure of the forelimbs and the ram to the right displays carpal valgus, indicative of ALD.
Frontal sections of distal radius from two ALD-affected animals. Images show mild (a) to moderate (b) irregular physeal thickening primarily affecting the distal radial physes (arrows). The irregular physeal thickening consists of both the proliferating and hypertrophic zones which extend down into the metaphysis.
Principal component analysis (PCA) of Rambouillet rams. In each panel, the PC1 is plotted on the x-axis and PC2 is plotted on the y-axis. (a) PCA with rams coded by phenotype, given by: red, ALD-affected rams; light blue, control rams; (b) PCA with rams coded by testing location, given by: yellow, NDSU; gray, UWY; (c) PCA with rams coded by test year, given by: violet, rams from test year 2019; black, 2020; green, 2021.
Multi-Manhattan and QQ plots displaying genome-wide association study results for incidence of ALD in Rambouillet rams. (a) Multi-Manhattan plot for the chi-square, fastGWA, and SAIGE models. Genome-wide significance is represented by the black line and defined by permutation testing (P-values < 2.00e−06); chromosome-wide significance is represented by the red line and defined by Bonferroni correction of the largest chromosome (P-values < 1.08e−05). (b) Quantile–quantile (QQ) plot for the chi-square, fastGWA, and SAIGE models displaying the expected versus observed P-values for each model.
of biological implications of GWAS results. (a) Deficiency of TSPAN18 gene expression may have negative repercussions on endochondral ossification through the downregulation of VEGFR2 leading to inhibition of the VEGF pathway and angiogenesis, or through decreased cell-surface expression of ORAI1 resulting in reduced Ca²⁺ signaling affecting osteoclast and osteoblast cell maturation. Predicted transcription factor binding site (TFBS) motifs, denoted by the dashed line, for NFE2L1, RUNX2 and TBX5 show loss of specificity with the rs160736723 SNP allele, potentially affecting TSPAN18 transcription; (b) Changes to NRG3 gene expression may impact chondrocyte growth and proliferation through the NRG3/ERBB4 pathway. Binding site motif specificities for transcription factors CREM, CREB1 and SOX9 are predicted to increase with the SNP allele at rs427563170; (c) Decreased gene expression of NOVA2 may decrease vascularization necessary for endochondral ossification. The SNP allele at rs416810983 results in decreased TFBS motif specificity of SOX6.
Angular limb deformity associated with TSPAN18, NRG3 and NOVA2 in Rambouillet rams

September 2023

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75 Reads

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2 Citations

Angular limb deformity (ALD) affects many species of livestock and companion animals. The mechanisms of ALD development are not well understood, but previous research suggests the involvement of genetic risk factors. A case-control genome-wide association study (GWAS) was conducted with 40 ALD-affected and 302 unaffected Rambouillet rams and 40,945 single nucleotide polymorphisms (SNPs). Forelimbs of 6 ALD-affected rams were examined and diagnosed with osteochondrosis. Genome-wide or chromosome-wide significant SNPs were positioned exonic, intronic or within the 3′UTR of genes TSPAN18, NRG3 and NOVA2, respectively. These genes have previously described roles related to angiogenesis and osteoblast, osteoclast and chondrocyte proliferation and differentiation, which suggests the possibility for their involvement in the pathogenesis of osteochondrosis. Functional consequences of SNPs were evaluated through transcription factor binding site analysis, which predicted binding sites for transcription factors of known importance to bone growth, including SOX6, SOX9 and RUNX2. The identification of genetic risk factors for ALD may help to improve animal welfare and production in Rambouillet, a breed known to be at risk for ALD development. This study proposes genes TSPAN18, NRG3 and NOVA2 as targets for further research towards understanding the etiology of ALD in Rambouillet sheep.


Breakthrough infections by SARS-CoV-2 variants boost cross-reactive hybrid immune responses in mRNA-vaccinated Golden Syrian Hamsters

May 2023

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92 Reads

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1 Citation

Hybrid immunity to SARS-CoV-2 provides superior protection to re-infection. We performed immune profiling studies during breakthrough infections in mRNA-vaccinated hamsters to evaluate hybrid immunity induction. mRNA vaccine, BNT162b2, was dosed to induce binding antibody titers against ancestral spike, but inefficient serum virus neutralization of ancestral SARS-CoV-2 or variants of concern (VoCs). Vaccination reduced morbidity and controlled lung virus titers for ancestral virus and Alpha but allowed breakthrough infections in Beta, Delta and Mu-challenged hamsters. Vaccination primed T cell responses that were boosted by infection. Infection back-boosted neutralizing antibody responses against ancestral virus and VoCs. Hybrid immunity resulted in more cross-reactive sera. Transcriptomics post-infection reflects both vaccination status and disease course and suggests a role for interstitial macrophages in vaccine-mediated protection. Therefore, protection by vaccination, even in the absence of high titers of neutralizing antibodies in the serum, correlates with recall of broadly reactive B and T-cell responses.


An analytical method for the quantitation (20-8,000 ppb) of Ergot Alkaloids in Wheat grain. v1

November 2022

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4 Reads

Ten ergot alkaloids are quantified in wheat and rye grains at concentrations ranging 20-8,000 ppb using HPLC-MS/MS. Briefly, 5 grams of ground sample is mixed with 40 mL of an extraction solution (ACN-water; 84/16, v/v + 200 mg/L Ammonium Carbonate, pH 8.5) was added to each tube, agitated for 30 min on a horizontal shaker at 150 cycles per min, let to sit for 1h to ensure adequate extraction of analytes and filtered through a Whatman 54 filter paper into a new tube. An aliquot of 4mL was pushed through Mycosep 150 Ergot column. An aliquot of 500 mL was mixed with 500 mL of dihydroergocristine at 100 ng/mL in the extraction buffer (internal standard) and centrifuged at 10 000 RPM for 5 min to remove any possible particulate matter. An aliquot of 100 mL was transferred into autosampler vial and injected (2 mL) into Agilent 6460C UHPLC–MS/MS equipped with guarded Agilent Zorbax Eclipse Plus C18 column (2.1 50mm, 1.8 micron). Validation data (in-house and via collaborative studies such as Blinded Method Test) are available in the following publication: https://pubmed.ncbi.nlm.nih.gov/33394021/


Citations (14)


... The immune response to SARS-CoV-2 infection is complex and influenced by both viral and host factors, with factors such as viral load, duration of exposure, genetics and the presence of comorbidities proving to be important factors [7][8][9][10] . Reinfection can occur as early as 3 months after the primary infection and it is more likely to be caused by antigenic distant variants that can escape virus neutralization by antibodies 11,12,[13][14][15][16] . Still, the correlates of protection and disease outcome from SARS-CoV-2 reinfection or secondary infection are yet to be determined and may involve adaptive as well as innate immune mediators. ...

Reference:

Outcome of SARS-CoV-2 reinfection depends on genetic background in female mice
Breakthrough infections by SARS-CoV-2 variants boost cross-reactive hybrid immune responses in mRNA-vaccinated Golden Syrian hamsters

... The epidermal growth factor-like domain of NRG3 binds to the ERBB4 receptor as a ligand, affecting the growth and differentiation of chondrocytes [51], and plays a role in bone formation and angiogenesis through interactions with proteins such as EGFR [52]. NRG3 is also associated with angular limb deformity [53]. Mutations in the RSPO2 gene can lead to interrupted limb development in animals, causing limb deformities [54]. ...

Angular limb deformity associated with TSPAN18, NRG3 and NOVA2 in Rambouillet rams

... The immune response to SARS-CoV-2 infection is complex and in uenced by both viral and host factorsviral load, duration of exposure, genetics and the presence of comorbidities have shown to be the most common pivotal factors 6-9 . Reinfection can occur as earlier as 3 months after the primary infection and it is more likely to be caused by antigenic distant variants 10,11 . Still, the correlates of protection and disease outcome from SARS-CoV-2 reinfection are yet to be determined and may involve adaptive as well as innate immune mediators. ...

Breakthrough infections by SARS-CoV-2 variants boost cross-reactive hybrid immune responses in mRNA-vaccinated Golden Syrian Hamsters

... The resistance gene cassettes with class 1 integrons are particularly common in L. monocytogenes. These cassettes often contain genes such as ermB, tetM, and dfrD encoding trimethoprim resistance, as well as other genes like fosX, lin, norB, and mprF that confer resistance to various antimicrobials [82,83]. A significant observation was the identification of MDR strains of L. monocytogenes that carry resistance genes on mobile genetic elements such as plasmids and transposons in both clinical and foodborne outbreaks [81]. ...

Comparative Genomics of Listeria monocytogenes Isolates from Ruminant Listeriosis Cases in the Midwest United States

Microbiology Spectrum

... There are a few areas of concern, which most notably include the ability to discern between clinically relevant organisms and whether the presence of resistance genes correlate with phenotypic resistance. [20][21][22][23][24][25] The aim of this study was to compare and contrast genotypic and phenotypic methods for bacterial identification and antimicrobial susceptibility of a homogenous bacterial sample acquired from cases of canine SBF. We hypothesised that there would be a quicker turnaround time for NGS versus culture. ...

Genomics Accurately Predicts Antimicrobial Resistance in Staphylococcus pseudintermedius Collected as Part of Vet-LIRN Resistance Monitoring
  • Citing Article
  • February 2021

Veterinary Microbiology

... Temperature and time appeared to decrease the concentration of ergovaline. In contrast, total ergot alkaloid concentration in rye was reported to be stable over days [11]. However, several studies demonstrated that total ergot alkaloid concentration was affected by longer time periods of months and years [1,8,10,12]. ...

Extensive Evaluation via Blinded Testing of an UHPLC-MS/MS Method for Quantitation of Ten Ergot Alkaloids in Rye and Wheat Grains
  • Citing Article
  • January 2021

Journal of AOAC International

... F − concentrations of less than 0.5 mg/l in drinking water lead to osteoporosis and dental caries. However, higher values, i.e., above 1.5 mg/l in water, cause various problems, e.g., from mottling and staining of teeth to dental or skeletal fluorosis and even miscarriages in pregnant women (Ather et al., 2022;Kelly et al., 2020). Similarly, elevated levels of NO 3 − cause, central nervous system impairment, methemoglobinemia, and intrauterine growth retardation in women (Apte et al., 2024;Golaki et al., 2022;Skold et al., 2011). ...

Equine dental and skeletal fluorosis induced by well water consumption

Journal of veterinary diagnostic investigation: official publication of the American Association of Veterinary Laboratory Diagnosticians, Inc

... Anelloviruses are circular negative-sense DNA viruses (Genome size: 1.6 to 3.9 kb) Varsani et al. 2021). Currently, 14 genera and 76 species are identified within the Anelloviridae family (Webb et al. 2020). Mammalian anelloviruses have been identified in a broad range of animals, including Otariidae and Phocidae families (Kluge et al. 2016;Smeele et al. 2018;Varsani et al. 2021). ...

Torque teno viruses in health and disease
  • Citing Article
  • May 2020

Virus Research

... Currently, oil based adjuvants are used with commercial vaccines to improve their immunogenicity [89]. Intranasal administration of immunogenic antigens with a porcine lung surfactant and Poly I:C with inactivated virions have separately been observed as effective in a research setting limited to H1N1 inactivated virions [193,194]. Intranasal delivery is further supported as a simple and effective administration technique using nanoparticles as a delivery vehicle for M2 antigens [195]. Here, pigs developed immunity to H1N1 through CMI without any detectable antibody response observed. ...

Delivery of a thermo-enzymatically treated influenza vaccine using pulmonary surfactant in pigs
  • Citing Article
  • November 2019

Veterinary Microbiology

... PED outbreaks have led to considerable losses in the livestock industry. PEDV was first discovered in England in 1971 and was subsequently identified in Belgium in 1978 [1]. The PED outbreak initially spread locally in Europe but has since spread to most Asian countries, including the Republic of Korea, Japan, Thailand, and China. ...

A Minimally Replicative Vaccine Protects Vaccinated Piglets Against Challenge With the Porcine Epidemic Diarrhea Virus