国外奶牛乳房炎相关基础研究新进展
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摘要
本文以奶牛乳房炎为关键词,在NCBI PubMed数据库中检索2014.01~2017.04的相关文献,并进行整理分析,对国外奶牛乳房炎的常见病原体研究新概况、与奶牛乳房炎相关的遗传学、发育生物学、免疫机制、诊断新技术等进行总结阐述,可为奶牛乳房炎的诊断与防控提供新的思路和技术。
The relevant papers abroad during 2014.01-2017.04,related dairy cow mastitis as the keywords by searching PubMed-NCBI database,were arranged and analysed in this review. The new general situation on researching the commom pathogens of dairy cow mastitis which was related to aspects such as genetics,developmental biology,immune mechanism,new techniques for diagnosing,are summarized,probably,affording references for diagnosing,preventing and treating dairy cow mastitis.
The relevant papers abroad during 2014.01-2017.04,related dairy cow mastitis as the keywords by searching PubMed-NCBI database,were arranged and analysed in this review. The new general situation on researching the commom pathogens of dairy cow mastitis which was related to aspects such as genetics,developmental biology,immune mechanism,new techniques for diagnosing,are summarized,probably,affording references for diagnosing,preventing and treating dairy cow mastitis.
引文
[1]Salimena AP,Lange CC,Camussone C,et al.Genotypic and phenotypic detection of capsular polysaccharide and biofilm formation in Staphylococcus aureus isolated from bovine milk collected from Brazilian dairy farms[J].Vet Res Commun,2016,40(3-4):97-106.
[2]Bardiau M,Caplin J,Detilleux J,et al.Existence of two groups of Staphylococcus aureus strains isolated from bovine mastitis based on biofilm formation,intracellular survival,capsular profile and agr-typing[J].Vet Microbiol,2016,185:1-6.
[3]Mello PL,Moraes Riboli DF,Pinheiro L,et al.Detection of enterotoxigenic potential and determi-nation of clonal profile in Staphylococcus aureus and Coagulase-Negative Staphylococci isolated from bovine subclinical mastitis in different Brazilian states[J].Toxins(Basel),2016,8(4):104.
[4]Felipe V,Morgante CA,Somale PS,et al.Evaluation of the biofilm forming ability and its associated genes in Staphylococcus species isolates from bovine mastitis in Argentinean dairy farms[J].Microb Pathog,2017,104:278-286.
[5]Veh KA,Klein RC,Ster C,et al.Genotypic and phenotypic characterization of Staphylococcus aureus causing persistent and nonpersistent subclinical bovine intramammary infections during lactation or the dry period[J].J Dairy Sci,2015,98(1):155-68.
[6]Sch?nborn S,Kr?mker V.Detection of the biofilm component polysaccharide intercellular adhesin in Staphylococcus aureus infectedcow udders[J].Vet Microbiol,2016,196:126-128.
[7]Boss R,Cosandey A,Luini M.Bovine Staphylococcus aureus:Subtyping,evolution,and zoonotic transfer[J].J Dairy Sci,2016,99(1):515-28.
[8]Cosandey A,Boss R,Luini M,et al.Staphylococcus aureus genotype B and other genotypes isolated from cow milk in European countries[J].J Dairy Sci,2016,99(1):529-540.
[9]Schmidt T,Kock MM,Ehlers MM.Molecular Characterization of Staphylococcus aureus isolated from bovine mastitis and close human contacts in South African dairy herds:genetic diversity and inter-species host transmission[J].Front Microbiol,2017,8:511.
[10]Benjamin AL,Green BB,Hayden LR,et al.Cow-to-cow variation in fibroblast response to a toll-like receptor 2/6agonist and its relation to mastitis caused by intramammary challenge with Staphylococcus aureus[J].J Dairy Sci,2015,98(3):1836-1850.
[11]Günther J,Czabanska A,Bauer I,et al.Streptococcus uberis strains isolated from the bovine mammary gland evade immune recognition by mammary epithelial cells,but not of macrophages[J].Vet Res,2016,47:13.
[12]Malvisi M,Stuknyt M,Magro G,et al.Antibacterial activity and immunomodulatory effects on a bovine mammary epithelial cell line exerted by nisin A-producing Lactococcus lactis strains[J].J Dairy Sci,2016,99(3):2288-2296.
[13]Mudaliar M,Tassi R,Thomas FC,et al.Mastitomics,the integrated omics of bovine milk in an experimental model of Streptococcus uberis mastitis:2.Label-free relative quantitative proteomics[J].Mol Biosyst,2016,12(9):2748-2761.
[14]Collado R,Prenafeta A,González-González L,et al.Probing vaccine antigens against bovine mastitis caused by Streptococcus uberis[J].Vaccine.,2016,34(33):3848-3854.
[15]Blagitz MG,Souza FN,Batista CF,et al.The neutrophil function and lymphocyte profile of milk from bovine mammary glands infected with Streptococcus dysgalactiae[J].J Dairy Res.,2015,82(4):460-469.
[16]Carvalho-Castro GA,Silva JR,Paiva LV,et al.Molecular epidemiology of Streptococcus agalactiae isolated from mastitis in Brazilian dairyherds[J].Braz J Microbiol.,doi:10.1016/j.bjm.2017.02.004.
[17]Gondaira S,Higuchi H,Nishi K.Mycoplasma bovis escapes bovine neutrophil extracellular traps[J].Vet Microbiol,2017,199:68-73.
[18]Kempf F,Slugocki C,Blum SE,et al.Genomic Comparative study of bovine mastitis Escherichia coli[J].PLoSOne,2016,11(1):e0147954.
[19]Porter J,Anderson J,Carter L,et al.In vitro evaluation of a novel bacteriophage cocktail as a preventative for bovine coliform mastitis[J].J Dairy Sci,2016,99(3):2053-2062.
[20]Roussel P,Cunha P,Porcherie A,et al.Investigating the contribution of IL-17A and IL-17F to the host response during Escherichia coli mastitis[J].Vet Res,2015,46(1):56.
[21]Johnzon CF,Artursson K,S?derlund R,et al.Mastitis pathogens with high virulence in a mouse model produce a distinct cytokine profile in vivo[J].Front Immunol,2016,7:368.
[22]Younis S,Javed Q,Blumenberg M.Meta-analysis of transcriptional responses to mastitis-causing Escherichia coli[J].PLoS One,2016,11(3):e0148562.
[23]Parker Gaddis KL,Cole JB,Clay JS,et al.Benchmarking dairy herd health status using routinely recorded herd summary data[J].J Dairy Sci,2016,99(2):1298-314.
[24]Verbeke J,Piccart K,Piepers S,et al.Somatic cell count and milk neutrophil viability of dairy heifers with specific CXCR1 genotypes following experimental intramammary infection with Staphylococcus chromogenes originating from milk[J].Vet J,2015,204(3):322-6.
[25]Verbeke J,Van Poucke M,Peelman L,et al.Differential expression of CXCR1 and commonly used reference genes in bovine milk somatic cells following experimental intramammary challenge[J].BMC Genet,2015,16:40.
[26]Durán Aguilar M,Román Ponce SI,Ruiz López FJ,et al.Genome-wide association study for milk somatic cell score in holstein cattle using copy number variation as markers[J].J Anim Breed Genet.,2017,134(1):49-59.
[27]Bagheri M,Moradi-Sharhrbabak M,Miraie-Ashtiani R,et al.Case-control approach application for finding a relationship between candidate genes and clinical mastitisin Holstein dairy cattle[J].J Appl Genet,2016,57(1):107-12.
[28]Ribeiro ES,Gomes G,Greco LF,et al.Carryover effect of postpartum inflammatory diseases on developmental biology and fertility in lactatingdairy cows[J].J Dairy Sci,2016,99(3):2201-20.
[29]Albaaj A,Foucras G,Raboisson D.High somatic cell counts and changes in milk fat and protein contents around insemination are negatively associated with conception in dairy cows[J].Theriogenology,2017,88:18-27.
[30]Merriman KE,Poindexter MB,Kweh MF,et al.Intramammary 1,25-dihydroxyvitaminD3 treatment increases expression of host-defense genes in mammary immune cells of lactating dairy cattle[J].J Steroid Biochem Mol Biol,2017,doi:10.1016/j.jsbmb.2017.02.006.
[31]Usman T,Yu Y,Zhai L,et al.Association of CD4 SNPs with fat percentage of Holstein cattle[J].Genet Mol Res,2016,15(3):gmr.15038697.
[32]Pinto IS,Fonseca I,Brand觔o HM,et al.Short-communication evaluation of perfused bovine udder for gene expression studies indairy cows[J].Genet Mol Res,2017,16(1):gmr16019637.
[33]Lanct觝t S,Fustier P,Taherian AR,et al.Effect of intramammary infusion of chitosan hydrogels at drying-off on bovine mammary gland involution[J].J Dairy Sci,2017,pii:S0022-0302(17)30058-9.
[34]Chuammitri P,Srikok S,Saipinta D,et al.The effects of quercetin on microRNA and inflammatory gene expression in lipopolysaccharide-stimulated bovine neutrophils[J].Vet World,2017,10(4):403-410.
[35]Zarrin M,Wellnitz O,van Dorland HA,et al.Induced hyperketonemia affects the mammary immune response during lipopolysaccharide challenge in dairycows[J].JDairy Sci,2014,97(1):330-339.
[36]Guerrero A,Dallas DC,Contreras S,et al.Peptidomic analysis of healthy and subclinically mastitic bovine milk[J].Int Dairy J,2015,46:46-52.
[37]Musayeva K,Sedereviěius A,elvyt R,et al.Concentration of lactoferrin and immunoglobulin G in cows'milk in relation to health status of the udder,lactation and season[J].Pol J Vet Sci,2016,19(4):737-744.
[38]Chinnappan R,Al Attas S,Kaman WE,et al.Development of magnetic nanoparticle based calorimetric assay for the detection of bovine mastitis in cow milk[J].Anal Biochem,2017,523:58-64.
[39]Damm M,Holm C,Blaabjerg M,et al.Differential somatic cell count-A novel method for routine mastitis screening in the frame of dairy herd improvement testing programs[J].J Dairy Sci,2017,100(6):4926-4940.
[40]Mason SE,Mullen KA,Anderson KL,et al.Pharmacokinetic analysis of thymol,carvacrol and diallyl disulfide after intramammary and topical applications in healthy organic dairy cattle[J].Food Addit Contam Part A Chem Anal Control Expo Risk Assess,2017:1-10.
[41]朱彤,韩映梅,王生华,等,中药对奶牛隐性乳房炎疗效观察[J].中兽医医药杂志,2014,33(4):71-72.
[42]韩映梅,朱彤,王生华,等,中药方剂及黄芪素对奶牛乳房炎及其生产性能的影响[J].中兽医医药杂志,2014,33(5):38-39.
[2]Bardiau M,Caplin J,Detilleux J,et al.Existence of two groups of Staphylococcus aureus strains isolated from bovine mastitis based on biofilm formation,intracellular survival,capsular profile and agr-typing[J].Vet Microbiol,2016,185:1-6.
[3]Mello PL,Moraes Riboli DF,Pinheiro L,et al.Detection of enterotoxigenic potential and determi-nation of clonal profile in Staphylococcus aureus and Coagulase-Negative Staphylococci isolated from bovine subclinical mastitis in different Brazilian states[J].Toxins(Basel),2016,8(4):104.
[4]Felipe V,Morgante CA,Somale PS,et al.Evaluation of the biofilm forming ability and its associated genes in Staphylococcus species isolates from bovine mastitis in Argentinean dairy farms[J].Microb Pathog,2017,104:278-286.
[5]Veh KA,Klein RC,Ster C,et al.Genotypic and phenotypic characterization of Staphylococcus aureus causing persistent and nonpersistent subclinical bovine intramammary infections during lactation or the dry period[J].J Dairy Sci,2015,98(1):155-68.
[6]Sch?nborn S,Kr?mker V.Detection of the biofilm component polysaccharide intercellular adhesin in Staphylococcus aureus infectedcow udders[J].Vet Microbiol,2016,196:126-128.
[7]Boss R,Cosandey A,Luini M.Bovine Staphylococcus aureus:Subtyping,evolution,and zoonotic transfer[J].J Dairy Sci,2016,99(1):515-28.
[8]Cosandey A,Boss R,Luini M,et al.Staphylococcus aureus genotype B and other genotypes isolated from cow milk in European countries[J].J Dairy Sci,2016,99(1):529-540.
[9]Schmidt T,Kock MM,Ehlers MM.Molecular Characterization of Staphylococcus aureus isolated from bovine mastitis and close human contacts in South African dairy herds:genetic diversity and inter-species host transmission[J].Front Microbiol,2017,8:511.
[10]Benjamin AL,Green BB,Hayden LR,et al.Cow-to-cow variation in fibroblast response to a toll-like receptor 2/6agonist and its relation to mastitis caused by intramammary challenge with Staphylococcus aureus[J].J Dairy Sci,2015,98(3):1836-1850.
[11]Günther J,Czabanska A,Bauer I,et al.Streptococcus uberis strains isolated from the bovine mammary gland evade immune recognition by mammary epithelial cells,but not of macrophages[J].Vet Res,2016,47:13.
[12]Malvisi M,Stuknyt M,Magro G,et al.Antibacterial activity and immunomodulatory effects on a bovine mammary epithelial cell line exerted by nisin A-producing Lactococcus lactis strains[J].J Dairy Sci,2016,99(3):2288-2296.
[13]Mudaliar M,Tassi R,Thomas FC,et al.Mastitomics,the integrated omics of bovine milk in an experimental model of Streptococcus uberis mastitis:2.Label-free relative quantitative proteomics[J].Mol Biosyst,2016,12(9):2748-2761.
[14]Collado R,Prenafeta A,González-González L,et al.Probing vaccine antigens against bovine mastitis caused by Streptococcus uberis[J].Vaccine.,2016,34(33):3848-3854.
[15]Blagitz MG,Souza FN,Batista CF,et al.The neutrophil function and lymphocyte profile of milk from bovine mammary glands infected with Streptococcus dysgalactiae[J].J Dairy Res.,2015,82(4):460-469.
[16]Carvalho-Castro GA,Silva JR,Paiva LV,et al.Molecular epidemiology of Streptococcus agalactiae isolated from mastitis in Brazilian dairyherds[J].Braz J Microbiol.,doi:10.1016/j.bjm.2017.02.004.
[17]Gondaira S,Higuchi H,Nishi K.Mycoplasma bovis escapes bovine neutrophil extracellular traps[J].Vet Microbiol,2017,199:68-73.
[18]Kempf F,Slugocki C,Blum SE,et al.Genomic Comparative study of bovine mastitis Escherichia coli[J].PLoSOne,2016,11(1):e0147954.
[19]Porter J,Anderson J,Carter L,et al.In vitro evaluation of a novel bacteriophage cocktail as a preventative for bovine coliform mastitis[J].J Dairy Sci,2016,99(3):2053-2062.
[20]Roussel P,Cunha P,Porcherie A,et al.Investigating the contribution of IL-17A and IL-17F to the host response during Escherichia coli mastitis[J].Vet Res,2015,46(1):56.
[21]Johnzon CF,Artursson K,S?derlund R,et al.Mastitis pathogens with high virulence in a mouse model produce a distinct cytokine profile in vivo[J].Front Immunol,2016,7:368.
[22]Younis S,Javed Q,Blumenberg M.Meta-analysis of transcriptional responses to mastitis-causing Escherichia coli[J].PLoS One,2016,11(3):e0148562.
[23]Parker Gaddis KL,Cole JB,Clay JS,et al.Benchmarking dairy herd health status using routinely recorded herd summary data[J].J Dairy Sci,2016,99(2):1298-314.
[24]Verbeke J,Piccart K,Piepers S,et al.Somatic cell count and milk neutrophil viability of dairy heifers with specific CXCR1 genotypes following experimental intramammary infection with Staphylococcus chromogenes originating from milk[J].Vet J,2015,204(3):322-6.
[25]Verbeke J,Van Poucke M,Peelman L,et al.Differential expression of CXCR1 and commonly used reference genes in bovine milk somatic cells following experimental intramammary challenge[J].BMC Genet,2015,16:40.
[26]Durán Aguilar M,Román Ponce SI,Ruiz López FJ,et al.Genome-wide association study for milk somatic cell score in holstein cattle using copy number variation as markers[J].J Anim Breed Genet.,2017,134(1):49-59.
[27]Bagheri M,Moradi-Sharhrbabak M,Miraie-Ashtiani R,et al.Case-control approach application for finding a relationship between candidate genes and clinical mastitisin Holstein dairy cattle[J].J Appl Genet,2016,57(1):107-12.
[28]Ribeiro ES,Gomes G,Greco LF,et al.Carryover effect of postpartum inflammatory diseases on developmental biology and fertility in lactatingdairy cows[J].J Dairy Sci,2016,99(3):2201-20.
[29]Albaaj A,Foucras G,Raboisson D.High somatic cell counts and changes in milk fat and protein contents around insemination are negatively associated with conception in dairy cows[J].Theriogenology,2017,88:18-27.
[30]Merriman KE,Poindexter MB,Kweh MF,et al.Intramammary 1,25-dihydroxyvitaminD3 treatment increases expression of host-defense genes in mammary immune cells of lactating dairy cattle[J].J Steroid Biochem Mol Biol,2017,doi:10.1016/j.jsbmb.2017.02.006.
[31]Usman T,Yu Y,Zhai L,et al.Association of CD4 SNPs with fat percentage of Holstein cattle[J].Genet Mol Res,2016,15(3):gmr.15038697.
[32]Pinto IS,Fonseca I,Brand觔o HM,et al.Short-communication evaluation of perfused bovine udder for gene expression studies indairy cows[J].Genet Mol Res,2017,16(1):gmr16019637.
[33]Lanct觝t S,Fustier P,Taherian AR,et al.Effect of intramammary infusion of chitosan hydrogels at drying-off on bovine mammary gland involution[J].J Dairy Sci,2017,pii:S0022-0302(17)30058-9.
[34]Chuammitri P,Srikok S,Saipinta D,et al.The effects of quercetin on microRNA and inflammatory gene expression in lipopolysaccharide-stimulated bovine neutrophils[J].Vet World,2017,10(4):403-410.
[35]Zarrin M,Wellnitz O,van Dorland HA,et al.Induced hyperketonemia affects the mammary immune response during lipopolysaccharide challenge in dairycows[J].JDairy Sci,2014,97(1):330-339.
[36]Guerrero A,Dallas DC,Contreras S,et al.Peptidomic analysis of healthy and subclinically mastitic bovine milk[J].Int Dairy J,2015,46:46-52.
[37]Musayeva K,Sedereviěius A,elvyt R,et al.Concentration of lactoferrin and immunoglobulin G in cows'milk in relation to health status of the udder,lactation and season[J].Pol J Vet Sci,2016,19(4):737-744.
[38]Chinnappan R,Al Attas S,Kaman WE,et al.Development of magnetic nanoparticle based calorimetric assay for the detection of bovine mastitis in cow milk[J].Anal Biochem,2017,523:58-64.
[39]Damm M,Holm C,Blaabjerg M,et al.Differential somatic cell count-A novel method for routine mastitis screening in the frame of dairy herd improvement testing programs[J].J Dairy Sci,2017,100(6):4926-4940.
[40]Mason SE,Mullen KA,Anderson KL,et al.Pharmacokinetic analysis of thymol,carvacrol and diallyl disulfide after intramammary and topical applications in healthy organic dairy cattle[J].Food Addit Contam Part A Chem Anal Control Expo Risk Assess,2017:1-10.
[41]朱彤,韩映梅,王生华,等,中药对奶牛隐性乳房炎疗效观察[J].中兽医医药杂志,2014,33(4):71-72.
[42]韩映梅,朱彤,王生华,等,中药方剂及黄芪素对奶牛乳房炎及其生产性能的影响[J].中兽医医药杂志,2014,33(5):38-39.