The complement in milk and defense of the bovine 
mammary gland against infections

Rainard, Pascal

doi:10.1051/vetres:2003025

Cited by 94 publications

(97 citation statements)

References 91 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…The marked difference in the onset of carprofen effects on chemotactic agents IL-8 and C5a could be explained by the location of mediator production. Interleukin-8 is directly produced by the epithelial cells in the mammary gland (Baggiolini and Clark-Lewis, 1992;Barber and Yang, 1998), whereas the bulk of C5a precursors are obtained from the blood through leakage of the disintegrated blood-milk barrier (Rainard et al, 1998;Rainard, 2003).…”

Section: Discussionmentioning

confidence: 99%

Effect of Carprofen Treatment Following Experimentally Induced Escherichia coli Mastitis in Primiparous Cows

Vangroenweghe

Duchateau

Boutet

et al. 2005

Journal of Dairy Science

View full text Add to dashboard Cite

Acute Escherichia coli mastitis is one of the major sources of economic loss in the dairy industry due to reduced milk production, treatment costs, discarded milk, and occasional fatal disease. Nonsteroidal antiinflammatory drugs (NSAIDs) are frequently used as adjunctive therapy to antibiotics. The objective of the current study was to evaluate the effect of carprofen treatment following infusion of Escherichia coli into the mammary glands of primiparous cows during the periparturient period. Severity of mastitis was scored based on the average milk production in the uninfected quarters on d +2 postinoculation and a clinical severity score. Carprofen was administered intravenously at 9 h postchallenge, when clinical signs of mastitis appeared. In previous work, efficacy of NSAIDs was mainly evaluated using clinical symptoms. In the present study, the effect of carprofen on innate immune response was also assessed by quantification of inflammatory mediators. All primiparous cows reacted as moderate responders throughout the experimental period. Primiparous cows were intramammarily inoculated with 1 × 10 4 cfu of E. coli P4:O32 in 2 left quarters. Analysis of blood and milk parameters, including IL-8, complement component C5a, lipopolysaccharide-binding protein (LBP), soluble CD14, prostaglandin E 2 , and thromboxane B 2 was performed from d 0 to d +6 relative to intramammary inoculation. Rectal temperature in carprofen-treated animals was lower than in control animals at 3 and 6 h posttreatment. Treatment also restored the decreased reticulorumen motility that occurs during E. coli mastitis to preinfection levels faster than in control animals. Carprofen treatment resulted 2361in an earlier normalization of the clinical severity score. Eicosanoid (prostaglandin E 2 and thromboxane B 2 ) production in milk tended to be inhibited by carprofen. No significant differences in the kinetic patterns of somatic cell count, IL-8, complement component C5a, LBP, and soluble CD14 were observed. In conclusion, carprofen treatment improved general clinical condition by effective antipyrexia and restoration of reticulorumen motility but did not significantly inhibit eicosanoid production. Carprofen treatment did not result in a significant decrease of chemotactic inflammatory mediators, IL-8 and C5a, and early innate immune molecules, sCD14 and LBP. Therefore, major modulatory effects from NSAID administration were not observed in this mastitis model, although a larger study might confirm some apparent trends obtained in the present results. (Key words: primiparous cow, carprofen, Escherichia coli mastitis, moderate inflammation) Abbreviation key: C5a = complement component 5a, COX = cyclo-oxygenase, HR = heart rate, LBP = LPSbinding protein, NSAID = nonsteroidal anti-inflammatory drug, PGE 2 = prostaglandin E 2 , PIH = postinfusion hour, RT = rectal temperature, sCD14 = soluble CD14, TMB = tetramethylbenzidine, TXB 2 = thromboxane B 2 .

show abstract

Section: Discussionmentioning

confidence: 99%

Effect of Carprofen Treatment Following Experimentally Induced Escherichia coli Mastitis in Primiparous Cows

Vangroenweghe

Duchateau

Boutet

et al. 2005

Journal of Dairy Science

View full text Add to dashboard Cite

show abstract

“…Lysozyme, lactoferrin and lactoperoxidase each possess the ability to suppress the growth of certain bacteria and were identified as minor milk proteins in the early part of the twentieth century . More recently, it has become apparent that milk also contains a range of additional antimicrobial proteins and peptides, including members of the b-defensin, complement, cathelicidin and S100 calgranulin families, as well as several acute phase proteins (Eckersall et al, 2001;Jia et al, 2001;Rainard, 2003;Swanson et al, 2004;Murakami et al, 2005;Lutzow et al, 2008). The role that two of these effector proteins play in contributing to the host-defence function of milk is described below, drawing on previously published work as well as our own unpublished data.…”

Section: Effector Proteins In Cows' Milkmentioning

confidence: 99%

Host-defence-related proteins in cows’ milk

Wheeler

Smolenski

Harris

et al. 2012

Animal

View full text Add to dashboard Cite

Milk is a source of bioactive molecules with wide-ranging functions. Among these, the immune properties have been the best characterised. In recent years, it has become apparent that besides the immunoglobulins, milk also contains a range of minor immune-related proteins that collectively form a significant first line of defence against pathogens, acting both within the mammary gland itself as well as in the digestive tract of the suckling neonate. We have used proteomics technologies to characterise the repertoire of host-defence-related milk proteins in detail, revealing more than 100 distinct gene products in milk, of which at least 15 are known host-defence-related proteins. Those having intrinsic antimicrobial activity likely function as effector proteins of the local mucosal immune defence (e.g. defensins, cathelicidins and the calgranulins). Here, we focus on the activities and biological roles of the cathelicidins and mammary serum amyloid A. The function of the immune-related milk proteins that do not have intrinsic antimicrobial activity is also discussed, notably lipopolysaccharide-binding protein, RNase4, RNase5/angiogenin and cartilage-glycoprotein 39 kDa. Evidence is shown that at least some of these facilitate recognition of microbes, resulting in the activation of innate immune signalling pathways in cells associated with the mammary and/or gut mucosal surface. Finally, the contribution of the bacteria in milk to its functionality is discussed. These investigations are elucidating how an effective first line of defence is achieved in the bovine mammary gland and how milk contributes to optimal digestive function in the suckling calf. This study will contribute to a better understanding of the health benefits of milk, as well as to the development of high-value ingredients from milk.

show abstract

“…The contribution of the complement system to the defense of the bovine mammary gland has recently been reviewed 372 P. Rainard, C. Riollet [142]. Complement is present in milk of healthy uninflamed glands at low but significant concentrations.…”

Section: Humoral Defensesmentioning

confidence: 99%

“…Deposition of the complement cleavage product C3b and its transformation into C3bi on bacteria favors their recognition by phagocytes through binding to the receptors CR1 and CR3, respectively [127]. Exudation of plasma provides the complement components which are absent in normal milk (in particular C1q), making possible the functioning of the classical pathway of activation, and the increase in the concentration of C3 augments the deposition of opsonic C3 fragments [142,144]. There is a temporally coincident increase in the BSA milk concentration and the generation of C5a in milk of E. coli mastitis [6,170].…”

Section: Humoral Defensesmentioning

confidence: 99%

Innate immunity of the bovine mammary gland

2006

Self Cite

View full text Add to dashboard Cite

-Understanding the immune defenses of the mammary gland is instrumental in devising and developing measures to control mastitis, the major illness of dairy ruminants. Innate immunity is an extremely broad field for investigation, and despite decades of research, our present knowledge of the innate defenses of the udder is incomplete. Yet, information is being gained on the recognition of pathogens by the mammary gland, and on several locally inducible defenses. The contribution of mammary epithelial cells to local defenses and to the mobilization of leucocytes is under growing scrutiny. Interactions of mastitis-causing bacteria such as Escherichia coli or Staphylococcus aureus and the mammary gland represents a suitable model for studies on innate immunity at an epithelium frontier. Powerful new research tools are radically modifying the prospects for the understanding of the interplay between the mammary gland innate defenses and mastitis-causing bacteria: genetic dissection of the immune response, microarray gene technology, transcriptomic methodologies and gene silencing by RNA interference will make possible the discovery of several of the key defense mechanisms which govern the susceptibility/resistance to mastitis at the molecular and genetic levels. It should then be possible to enhance the resistance of dairy ruminants to mastitis through immunomodulation and genetic improvement. mastitis / cattle / innate immunity / inflammation / milk

show abstract

The complement in milk and defense of the bovine mammary gland against infections

Cited by 94 publications

References 91 publications

Effect of Carprofen Treatment Following Experimentally Induced Escherichia coli Mastitis in Primiparous Cows

Effect of Carprofen Treatment Following Experimentally Induced Escherichia coli Mastitis in Primiparous Cows

Host-defence-related proteins in cows’ milk

Innate immunity of the bovine mammary gland

Contact Info

Product

Resources

About