Is the IL1RA/IL1B Ratio a Suitable Biomarker for Subclinical Endometritis in Dairy Cows?

The adequate expression of cytokines is essential for the prevention and healing of bovine endometrial inflammation. This study investigated the intra-uterine concentration of the proinflammatory cytokine interleukin (IL)1B and its antagonist IL1RA in cows with and without subclinical endometritis (SE). Samples were taken from 37 uteri at the abattoir and 26 uteri in vivo. Uterine secretion samples were classified as showing no signs of SE (SEneg; polymorphonuclear neutrophil granulocyte (PMN) < 5%) or showing signs of SE (SEpos; PMN ≥ 5%). Concentrations and ratios for IL1B and IL1RA were measured using a commercial and a newly established AlphaLISA kit, respectively. In both groups, a higher concentration of IL1B was detected in the SEpos group compared with the SEneg group (abattoir: p = 0.027; in vivo p < 0.001). No significant differences were observed in the concentration of IL1RA (p > 0.05). In uterine secretion samples retrieved in vivo, a lower IL1RA/IL1B ratio was detected in the SEpos group compared with the SEneg group (p = 0.002). The results of this study highlight the important role of IL1B and IL1RA during endometritis and the potential of the IL1RA/IL1B ratio as a possible biomarker for SE.

Concentration-Dependent Type 1 Interferon-Induced Regulation of MX1 and FABP3 in Bovine Endometrial Explants.

The inadequate maternal recognition of embryonic interferon τ (IFNτ) might explain subfertility in cattle. This study aimed at modeling the inducibility of type 1 interferon receptor subunits 1/2 (IFNAR1/2), mimicking competition between IFNτ and infection-associated interferon α (IFNα), and simulating type 1 interferon pathways in vitro. Endometrial explants (n = 728 from n = 26 healthy uteri) were collected at the abattoir, challenged with IFNτ and/or IFNα in different concentrations, and incubated for 24 h. Gene expression analysis confirmed the inducibility of IFNAR1/2 within this model, it being most prominent in IFNAR2 with 10 ng/mL IFNα (p = 0.001). The upregulation of interferon-induced GTP-binding protein (MX1, classical pathway) was higher in explants treated with 300 ng/mL compared to 10 ng/mL IFNτ (p < 0.0001), whereas the non­classical candidate fatty acid binding protein 3 (FABP3) exhibited significant downregulation comparing 300 ng/mL to 10 ng/mL IFNτ. The comparison of explants challenged with IFNτ + IFNα indicated the competition of IFNτ and IFNα downstream of the regulatory factors. In conclusion, using this well-defined explant model, interactions between infection-associated signals and IFNτ were indicated. This model can be applied to verify these findings and to mimic and explore the embryo-maternal contact zone in more detail.

Functional characterization of the chicken cationic amino acid transporter-2 isoforms.

Utilization of lysine and arginine by mammalian skeletal muscle is due in large part to the system y(+) cationic amino acid transporters (CAT), particularly CAT-2A. The chicken CAT-2 (cCAT-2) gene is alternatively spliced to produce three isoforms (cCAT-2A/B/C). Chicken (Gallus gallus) CAT-2 isoforms were transiently and stably expressed in mammalian cell lines to determine cCAT-2 isoform cellular localization and transport properties. The cCAT-2A protein localized to the plasma membrane and the cCAT-2B protein localized to the cytoplasm juxtaposed to the plasma membrane. The cCAT-2C protein localized non-specifically throughout the cytoplasm. The cCAT-2A protein exhibited saturable transport. The K(t) of cCAT-2A for lysine using transient transfection was 2.6mM and the V(max) was 11.9pmol/mg protein/min. The K(t) of cCAT-2A for lysine using stable transfection was 7.9mM and the V(max) was 12.8pmol/mg protein/min. Transient and stable transfections of cCAT-2B or cCAT-2C resulted in no lysine or arginine transport. These data indicate that cCAT-2A is a low affinity, high velocity transporter for lysine and arginine and is the cCAT-2 isoform responsible for lysine and arginine transport in avian skeletal muscle.

Molecular cloning and characterization of the chicken cationic amino acid transporter-2 gene.

The system y(+) cationic amino acid transporters (CATs) play an important role in the regulation of lysine and arginine utilization. We have characterized the genomic organization and tissue transcription of the chicken CAT-2 (cCAT-2) isoforms from pectoralis muscle. The primary cCAT-2 transcript is alternatively spliced within the same position of the mRNA to produce cCAT-2A and cCAT-2B isoforms that share high nucleotide homology with their mammalian counterparts. We also identified a novel third CAT-2 isoform, cCAT-2C. This isoform contains a premature termination codon and studies in the chicken LMH cell line show that cCAT-2C mRNA is degraded by the nonsense-mediated mRNA decay pathway. All three cCAT-2 isoforms are transcribed in liver, pectoralis, gastrocnemius and heart. Chicken cCAT-2A was the predominant cCAT-2 isoform in liver, pectoralis and gastrocnemius. Analysis of the 5'-untranslated region of cCAT-2 identified multiple cCAT-2 promoters. Chicken CAT-2 promoter usage was tissue dependent and was not responsible for cCAT-2 isoform production. Analysis of genomic sequence upstream cCAT-2 promoter regions revealed binding sites for transcription factors involved in amino acid sensing, hormone signaling and immune function. These results provide insight into the role of the cCAT-2 gene and its regulation of lysine and arginine utilization in aves.