Dairy cattle are susceptible to increased incidence and severity of disease during the periparturient period. Increased health disorders have been associated with alterations in bovine immune mechanisms. Many different aspects of the bovine immune system change during the periparturient period, but uncontrolled inflammation is a dominant factor in several economically important disorders such as metritis and mastitis. In human medicine, the metabolic syndrome is known to trigger several key events that can initiate and promote uncontrolled systemic inflammation. Altered lipid metabolism, increased circulating concentrations of non-esterified fatty acids and oxidative stress are significant contributing factors to systemic inflammation and the development of inflammatory-based diseases in humans. Dairy cows undergo similar metabolic adaptations during the onset of lactation, and it was postulated that some of these physiological events may negatively impact the magnitude and duration of inflammation. This review will discuss how certain types of fatty acids may promote uncontrolled inflammation either directly or through metabolism into potent lipid mediators. The relationship of increased lipid metabolism and oxidative stress to inflammatory dysfunction will be reviewed as well. Understanding more about the underlying cause of periparturient health disorders may facilitate the design of nutritional regimens that will meet the energy requirements of cows during early lactation and reduce the susceptibility to disease as a function of compromised inflammatory responses.
Mastitis is broadly defined as the inflammation of the mammary gland; however, the concept of mastitis is customized to address its social and clinical impact in the case of humans and the health, welfare, and economic consequences for other mammals. There are many microbial, host, and environmental factors that influence the development of mastitis. Some are common to all mammals as well as inherent to each species. Together these factors influence the most prevalent etiological agents for each species and might determine the possibility of interspecies transmission with its consequences to public health. The present review will summarize and compare reports on mastitis etiology and its epidemiology in humans and food animal species.
The periparturient period is characterized by sudden changes in metabolic and immune cell functions that predispose dairy cows to increased incidence of disease. Metabolic changes include alterations in the energy balance that lead to increased lipomobilization with consequent elevation of plasma nonesterified fatty acids (NEFA) concentrations. The objective of this study was to establish the influence of lipomobilization on fatty acid profiles within plasma lipid fractions and leukocyte phospholipid composition. Blood samples from 10 dairy cows were collected at 14 and 7 d before due date, at calving, and at 7, 14, and 30 d after calving. Total lipids and lipid fractions were extracted from plasma and peripheral blood mononuclear cells. The degree of lipomobilization was characterized by measurement of plasma NEFA concentrations. The fatty acid profile of plasma NEFA, plasma phospholipids, and leukocyte phospholipids differed from the composition of total lipids in plasma, where linoleic acid was the most common fatty acid. Around parturition and during early lactation, the proportion of palmitic acid significantly increased in the plasma NEFA and phospholipid fractions with a concomitant increase in the phospholipid fatty acid profile of leukocytes. In contrast, the phospholipid fraction of long-chain polyunsaturated fatty acids in leukocytes was diminished during the periparturient period, especially during the first 2 wk following parturition. This study showed that the composition of total plasma lipids does not necessarily reflect the NEFA and phospholipid fractions in periparturient dairy cows. These findings are significant because it is the plasma phospholipid fraction that contributes to fatty acid composition of membrane phospholipids. Increased availability of certain saturated fatty acids in the NEFA phospholipid fractions may contribute to altered leukocyte functions during the periparturient period.
Elevated concentrations of plasma fatty acids in transition dairy cows are significantly associated with increased disease susceptibility and poor lactation performance. The main source of plasma fatty acids throughout the transition period is lipolysis from adipose tissue depots. During this time, plasma fatty acids serve as a source of calories mitigating the negative energy balance prompted by copious milk synthesis and limited dry matter intake. Past research has demonstrated that lipolysis in the adipose organ is a complex process that includes not only the activation of lipolytic pathways in response to neural, hormonal, or paracrine stimuli, but also important changes in the structure and cellular distribution of the tissue in a process known as adipose tissue remodeling. This process involves an inflammatory response with immune cell migration, proliferation of the cellular components of the stromal vascular fraction, and changes in the extracellular matrix. This review summarizes current knowledge on lipolysis in dairy cattle, expands on the new field of adipose tissue remodeling, and discusses how these biological processes affect transition cow health and productivity.
High concentrations of plasma nonesterified fatty acids (NEFA), a direct measure of lipolysis, are considered a risk factor for displaced abomasum (DA) and other clinical diseases. In nonruminants, uncontrolled lipolysis is commonly associated with adipose tissue macrophage (ATM) infiltration. In dairy cows, recent studies report ATM infiltration in specific adipose depots during the first week of lactation. Depending on their phenotype, ATM can be broadly classified as classically activated (M1) or alternatively activated (M2). The M1 ATM are considered pro-inflammatory, whereas M2 ATM enhance inflammation resolution. Currently, it is not known whether multiparous transition cows with DA have increased ATM infiltration, and the predominant phenotype of these mononuclear cells remains unclear. The objective of this study was to characterize ATM infiltration into different adipose tissue depots in transition cows with DA (days in milk=7.8±4.6 d; body condition score=2.95±0.10; n=6). Serum samples and biopsies from omental (OM) and subcutaneous (SC) fat depots were obtained during corrective surgery for DA. In an effort to compare ATM infiltration in DA cows with that of healthy cows in anabolic state (AS), adipose biopsies and blood samples were collected from nonlactating, nongestating dairy cows at the time of slaughter (body condition score=3.75±0.12; n=6). Adipose tissues were digested and cells from the stromal vascular fraction (SVF) were analyzed using flow cytometry to establish cell surface expression of specific macrophage markers including CD14, CD11c, CD163, and CD172a. Tissue sections were analyzed by immunohistochemistry to assess ATM localization. Cows with DA were ketotic and had plasma NEFA above 1.0 mEq/L. The same group of cows had significant infiltration of ATM in OM characterized by increased numbers of SVF cells expressing CD14 and CD172a. At the same time, expression of CD11c, and CD163 was significantly higher in SVF from OM and SC of DA cows compared with those from AS animals. Expression of M1 macrophage inflammatory phenotype-related genes CCL2, IL6, and TNFα in SVF from cows with DA was significantly higher than that in healthy cows (AS). Significant populations of ATM in OM and SC depots of cows with DA were localized in multiple cellular aggregates that included multinucleated cells. In contrast, ATM in AS cows were fewer and randomly localized in both SC and OM. Together, these results indicate that infiltration of classically activated ATM is a concurrent finding in DA cases and may be associated with metabolic stress around parturition contributing to the pro-inflammatory status of transition dairy cows. Future studies are needed to establish whether ATM infiltration is more pronounced in cows with DA compared with healthy dairy cows at the same lactation stage and if this increased mononuclear immune cell trafficking has any pathophysiological significance.
Brown adipocytes (BA) generate heat in response to sympathetic activation and are the main site of nonshivering thermogenesis in mammals. Although most BA are located in classic brown adipose tissue depots, BA are also abundant in the inguinal white adipose tissue (iWAT) before weaning. The number of BA is correlated with the density of sympathetic innervation in iWAT; however, the role of continuous sympathetic tone in the establishment and maintenance of BA in WAT has not been investigated. BA marker expression in iWAT was abundant in weaning mice but was greatly reduced by 8 wk of age. Nonetheless, BA phenotype could be rapidly reinstated by acute β3-adrenergic stimulation with CL-316,243 (CL). Genetic tagging of adipocytes with adiponectin-CreERT2 demonstrated that CL reinstates uncoupling protein 1 (UCP1) expression in adipocytes that were present before weaning. Chronic surgical denervation dramatically reduced the ability of CL to induce the expression of UCP1 and other BA markers in the tissue as a whole, and this loss of responsiveness was prevented by concurrent treatment with CL. These results indicate that ongoing sympathetic activity is critical to preserve the ability of iWAT fat cells to express a BA phenotype upon adrenergic stimulation.
Excessive rates of demand lipolysis in the adipose tissue (AT) during periods of negative energy balance (NEB) are associated with increased susceptibility to disease and limited lactation performance. Lipolysis induces a remodeling process within AT that is characterized by an inflammatory response, cellular proliferation, and changes in the extracellular matrix (ECMT). The adipose tissue macrophage (ATM) is a key component of the inflammatory response. Infiltration of ATM-forming cellular aggregates was demonstrated in transition cows, suggesting that ATM trafficking and phenotype changes may be associated with disease. However, it is currently unknown if ATM infiltration occurs in dairy cows only during NEB states related to the transition period or also during NEB-induced lipolysis at other stages of lactation. The objective of this study was to evaluate changes in ATM trafficking and inflammatory phenotypes, and the expression of genetic markers of AT remodeling in healthy late-lactation cows during feed restriction-induced NEB. After a 14-d (d −14 to d −1) preliminary period, Holstein cows were randomly assigned to 1 of 2 feeding protocols, ad libitum (AL) or feed restriction (FR), for 4 d (d 1-4). Caloric intake was reduced in FR to achieve a targeted energy balance of −15 Mcal/d of net energy for lactation. Omental and subcutaneous AT samples were collected laparoscopically to harvest stromal vascular fraction (SVF) cells on d −3 and 4. The FR induced a NEB of −14.1 ± 0.62 Mcal/d of net energy for lactation, whereas AL cows remained in positive energy balance (3.2 ± 0.66 Mcal/d of NE L ). The FR triggered a lipolytic response reflected in increased plasma nonesterified fatty acids (0.65 ± 0.05 mEq/L on d 4), enhanced phosphorylation of hormone sensitive lipase, and reduced adipocyte diameter.Flow cytometry and immunohistochemistry analysis revealed that on d 4, FR cows had increased numbers of CD172a + , an ATM (M1 and M2) surface marker, cells in SVF that were localized in aggregates. However, FR did not alter the number of SVF cells expressing M1 markers (CD14 and CD11c) or M2 markers (CD11b and CD163). This finding contrasts with the predominately M1 phenotype observed previously in ATM from clinically diseased cows. No changes were observed in the expression of ECMT-related or cell proliferation markers. In summary, an acute 4-d lipolytic stimulus in late-lactation dairy cows led to ATM infiltration with minimal changes in inflammatory phenotype and no changes in ECMT. These results underscore that physiological changes related to parturition, the onset of lactation, extended periods of lipolysis, or a combination of these can induce intense AT remodeling with enhanced ATM inflammatory phenotype expression that may impair the metabolic function of AT in transition dairy cattle.
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