Castration induced circRNA expressional changes in subcutaneous adipose tissue of male pigs

Circular RNAs (circRNAs) participated in regulation of lipid metabolism; however, its functional role on castration-induced lipid deposition has not been deeply researched. So in this research, we firstly compared circRNAs expressional differences in subcutaneous adipose tissue between intact and castrated male Huainan pigs. A total of 6116 differentially expressed circRNAs (DECs) were detected between these two groups (|log₂foldchange| ≥ 1 and p_adj ≤ 0.05); GO and KEGG analysis showed that their parent genes were mainly enriched in metabolism-related pathway. And TGF-beta, insulin, AMPK, and MAPK pathways might play vital role in castration-induced lipid deposition. The miRNAs enriched in the constructed circRNA–miRNA network were mainly participated in adipogenesis and lipid metabolism, such as miR-143a-3p, miR-378, and miR-195. And it was verified that testosterone upregulated miR-181a but downregulated circ_0005912 expression in a dose-dependent manner in porcine intramuscular adipocytes, and overexpression of miR-181a inhibited circ_0005912. Taken together, these DECs may participate in the regulation of lipid metabolism after castration by reaction with miRNAs, which indicated the novel role of circRNAs in castration-induced lipid deposition.     

State of the art: Stem cells in equine regenerative medicine

According to Greek mythology, Prometheus' liver grew back nightly after it was removed each day by an eagle as punishment for giving mankind fire. Hence, contrary to popular belief, the concept of tissue and organ regeneration is not new. In the early 20th century, cell culture and ex vivo organ preservation studies by Alexis Carrel, some with famed aviator Charles Lindbergh, established a foundation for much of modern regenerative medicine. While early beliefs and discoveries foreshadowed significant accomplishments in regenerative medicine, advances in knowledge within numerous scientific disciplines, as well as nano‐ and micromolecular level imaging and detection technologies, have contributed to explosive advances over the last 20 years. Virtually limitless preparations, combinations and applications of the 3 major components of regenerative medicine, namely cells, biomaterials and bioactive molecules, have created a new paradigm of future therapeutic options for most species. It is increasingly clear, however, that despite significant parallels among and within species, there is no ‘one‐size‐fits‐all’ regenerative therapy. Likewise, a panacea has yet to be discovered that completely reverses the consequences of time, trauma and disease. Nonetheless, there is no question that the promise and potential of regenerative medicine have forever altered medical practices. The horse is a relative newcomer to regenerative medicine applications, yet there is already a large body of work to incorporate novel regenerative therapies into standard care. This review focuses on the current state and potential future of stem cells in equine regenerative medicine.     

Ultrasound‐guided lipoaspiration for mesenchymal stromal cell harvest in the horse

Mesenchymal stromal cells (MSC) are being used to treat a variety of conditions in the horse. Traditional lipectomy and bone marrow aspiration for MSC harvest have disadvantages including cosmetic issues with lipectomy and extensive time for cell expansion after bone marrow harvests. This article describes a new technique of adipose harvest in the horse, utilising ultrasound and liposuction that can be safely and effectively performed in an ambulatory environment. Ultrasound‐guided lipoaspiration offers a minimally invasive technique using small portals and a diffuse area of collection significantly improving aesthetic outcome and increasing the likelihood of treating within a matter of days vs. a matter of weeks.     

An improved method for the study of equine haptoglobin heterogeneity

Equine serum haptoglobin was separated by polyacrylamide gel isoelectric focusing and visualized by protein staining or Western blotting. Conventional protein staining revealed up to three bands in the pI range 4.17 to 4.44. The blotting technique, however, showed an anodal group of 8 to 10 bands with a pI range of 4.11 to 4.52 and a cathodal group of 4 to 6 bands with a range of 4.55 to 5.14. The blotting method revealed that equine haptoglobin migrates outside the prealbumin area, in contrast to previous reports.     

ORIGINAL ARTICLE: Putative reference genes for gene expression studies in propionate and β‐hydroxybutyrate treated bovine adipose tissue explants

Accurate gene expression normalization using a stable reference gene (RG) improves the reliability of quantitative real‐time PCR (qPCR) results. Therefore, a validation of RGs should be done before their use. Only few studies on RGs have been done in cattle, and none in bovine adipose tissue (AT) explants, therefore, we characterize the effects of an in vitro treatment with propionate and β‐hydroxybutyric acid (BHB) on the mRNA content of these RGs comparing the output data from the geNorm^TM and the Normfinder^© program. geNorm^TM and Normfinder^© estimated the most stable RGs in the following sequence for subcutaneous and for retroperitoneal AT explants treated with propionate: low density lipoprotein receptor‐related protein 10 (LRP10) > hippocalcin‐like 1 (HPCAL1) > glyceraldehyde‐phosphate‐dehydrogenase (GAPDH) > ribosomal protein S9 (RPS9) > RNA polymerase II (Pol II) > beta2 actin (ACTB) > 18S ribosomal RNA (18S rRNA). BHB treated AT explants yielded a different stability ranking for RGs using geNorm^TM: HPCAL1, GAPDH > Pol II > LRP10 > ACTB > RPS9 > 18S rRNA. Normfinder^© estimated a different stability ranking for the RGs as shown in the following sequence for subcutaneous and retroperitoneal AT explants treated with BHB: HPCAL1 > Pol II > GAPDH > ACTB > LRP10 > RPS9 > 18S rRNA. Subsequent pairwise analysis of variation of RGs using geNorm^TM suggested that LRP10, HPCAL1 and GAPDH should be used for accurate normalization of subcutaneous and retroperitoneal AT explants treated with propionate, while HPCAL1, GAPDH and Pol II should be used for BHB treatment.     

Soft tissue sarcomas in the pharyngeal region of a 5‐year‐old Quarter Horse mare

This case report describes the identification of multiple soft tissue sarcomas in the pharyngeal region of a 5‐year‐old Quarter Horse mare. Diagnostic work‐up included physical examination, radiography, ultrasonography, endoscopic examination of upper airways and guttural pouch, and post mortem examination with histopathology. Humane euthanasia was indicated due to the chronicity of the condition, prognosis and financial constraints.     

Gene expression of resistin and TNF-α in adipose tissue of Japanese Black steers and Holstein steers

The aim of the present study was to compare the expression of adipose tissue mRNA related to glucose metabolism between Japanese Black steers (n = 5) and Holstein steers (n = 5). We examined the expression of the resistin, tumor necrosis factor‐α (TNF‐α), glucose transporter 1 (GLUT1) and growth hormone receptor (GHR) genes using real‐time polymerase chain reaction of cDNA in adipose tissue. The cDNA sequence identified by 5′/3′‐rapid amplification of cDNA and the deduced amino acid sequence were highly conserved in human, porcine and murine resistin. Expression of resistin mRNA was significantly greater in Holstein steers than in Japanese Black steers. In contrast, expression of TNF‐α mRNA was slightly greater in Japanese Black steers. Expression of GHR mRNA was significantly greater in Japanese Black steers compared with the Holstein steers, although there was no significant difference in the expression of GLUT1 mRNA. However, the plasma non‐esterified fatty acid (NEFA), glucose, insulin and growth hormone concentrations did not differ between Japanese Black and Holstein steers. The present results show that there is a difference in the expression level of mRNA related to glucose metabolism between Japanese Black steers and Holstein steers.     

β‐Carotene is incorporated or mobilized along with triglycerides in bovine adipose tissue in response to insulin or epinephrine

Pasture fed cattle ingest substantial amounts of β‐carotene (β‐C). Not all of the carotenoid compound is transformed into vitamin A, but the surplus is deposited in adipose tissue (AT). The mechanisms of β‐C incorporation and mobilization are unknown. Two experiments were conducted using explants from bovine AT cultured in vitro. First, β‐C incorporation by explants from three animals was examined with different β‐C concentrations (0, 1, 5 and 20 μm ) and different times of incubation (every 5 h up to 25 h). The data showed a significant increase of β‐C concentration in explants only for 20 μm β‐C. Secondly, effects of insulin and epinephrine on β‐C and triglyceride (TG) contents of explants were studied. Explants from six animals were incubated with either hormone and 0 or 20 μm β‐C for 20 h. Both TG and β‐C contents were affected positively by insulin and negatively by epinephrine. Interestingly, changes in ratios of β‐C/TG (hormone vs. control) were similar (1.7 × 10^?3 and 1.8 × 10^?3), respectively, for insulin and epinephrine, indicating that β‐C level is directly related to TG content. We also report the presence of mRNA for β‐C 15, 15′ oxygenase in bovine AT. The in vitro culture system using explants from bovine AT is a promising model to investigate factors that might affect the accumulation and metabolism of β‐C.     

Arthroscopically‐assisted removal of an osteochondral fragment from the equine elbow using a caudo‐medial approach

An 8‐year‐old Polo pony mare was admitted for investigation of lameness related to swelling of the elbow. An intra‐articular fragment from the proximo‐medial radius was identified on radiographic examination. The fragment was removed arthroscopically under general anaesthesia via a caudo‐medial approach to the elbow joint.     

An update on equine post‐operative ileus: Definitions,pathophysiology and management

Post‐operative ileus (POI) is a serious condition which any horse undergoing abdominal surgery is at risk of developing, leading to increased hospitalisation time and resulting costs. Advances in the understanding of the development of equine POI are mainly based on human and rodent literature, where manipulation‐induced inflammation has been identified as a trigger, with activation of resident muscularis externa macrophages playing a crucial role in the pathophysiology. Despite many pharmacological trials in all species, there is no single completely successful treatment for POI, highlighting that the condition is multifactorial in cause and requires a multimodal approach to minimise its incidence.     

Enhanced protocol for CD14+ cell enrichment from equine peripheral blood via anti‐human CD14 mAb and automated magnetic activated cell sorting

Reasons for performing study: CD14 positive (CD14+) cells are the precursor cells of monocyte‐derived dendritic cells (DCs). In horses their potent antigen‐presenting capacity and ability to induce an effective immune response classify these cells suitable for several therapeutic approaches such as for equine sarcoid. However, in horses, the generation efficiency of DCs from adherent peripheral blood mononuclear cells (PBMCs) is currently still poor. Objectives: Establishment of a simple short protocol to enhance DC generation in horses by using a human CD14 monoclonal antibody (mAb) and an automated magnetic activated cell sorting (MACS) system. Methods: Peripheral blood mononuclear cells were isolated from fresh heparinised blood samples of 3 horses and primarily stained for flow cytometric analysis (FACS) with a mAb against human CD14 as well as a secondary phycoerythrin (PE) conjugated antibody to determine the initial percentage of CD14 cells in the sample. Peripheral blood mononuclear cells were used for automated MACS using the same primary and secondary antibodies and analysed by FACS. CD14+ selected cells were cultured for 4 days adding granulocyte‐macrophage colony‐stimulating factor (GM‐CSF) and interleukin‐4 (IL‐4) to the culture media. Dendritic cell generation was assessed analysing cell morphology and surface marker expression (hCD83, hCD86, eqMHCII). Results: Prior to selection, the mean percentage of CD14+ cells in the total cell population was 5.5%, further gaiting of this cell population resulted in 78.46% CD14+ monocytes. After our positive selection the mean percentage of CD14+ cells in the population was 98% without affecting viability. After culture, DC yield was 2‐fold higher than in previous published outcomes. Conclusions: The additional CD14 cell separation step after PBMC isolation significantly amplified the number of CD14+ cells, increasing the number of generated DCs. Potential relevance: The number of DCs available is critical for further use of these cells and the herein described protocol will therefore help to improved DC generation for therapeutic approaches in horses.