病原感染后鸡miRNAs调控的研究进展

doi:10.16431/j.cnki.1671-7236.2022.05.031

Abstract

Abstract: microRNAs (miRNAs) are a class small non-coding RNAs with short single chain.Both during normal development and the occurrence and development of disease,miRNA can bind to the target mRNA,participate in post-transcriptional regulation of genes and play an important role.Recently,with the in-depth study of miRNAs,more and more evidence showed that pathogen infection will change the expression level of host miRNAs.These differentially expressed miRNAs can actively participate in the occurrence and development of the disease,and participate in immune function,autophagy,inflammation,metabolism and other biological processes to inhibit or promote the development of the disease by inhibiting target genes expression.In addition,host miRNAs as a small RNA involved in post-transcriptional regulation,during the pathogens infection process,chicken miRNAs not only target their own genes to regulate chicken innate immune signals but also target pathogenic genes to affect pathogen adsorption,invasion,proliferation,and so on.This paper mainly introduces the biosynthesis and function of miRNAs and the regulatory role and mechanism of chicken miRNAs in the invasion and pathogenesis of some viruses,bacteria and parasites,and briefly describes the regulation strategies of chicken miRNAs after different pathogens infection.This paper reviews the biogenesis and function of miRNAs and miRNA regulatory mechanism during pathogen invasion and pathogenic process,briefly describes the regulation strategy of chicken miRNAs after infection with different pathogens,to provide some references for the diagnosis,treatment,prevention and control of chicken disease from the point of view of chicken miRNAs.

Key words: miRNA; viruses; bacteria; immune response; chicken

CLC Number:

S855

ZHANG Yuming, CHEN Qiaoguang, HOU Zhaofeng, LIU Dandan, TAO Jianping, XU Jinjun. Research Progress on Chicken miRNAs and Their Regulation Role After Pathogenic Infection[J]. China Animal Husbandry & Veterinary Medicine, 2022, 49(5): 1908-1916.

References

[1] MOLNÁR A,SCHWACH F,STUDHOLME D J,et al.miRNAs control gene expression in the single-cell alga Chlamydomonas reinhardtii[J].Nature,2007,447(7148):1126-1129.
[2] LEE R C,FEINBAUM R F,AMBROS V.The C.elegans heterochronic gene lin-4 encodes small RNAs with antisense complementarity to lin-14[J].Cell,1993,75(5):843-854.
[3] ROOIJ E.The art of microRNA research[J].Circulation Research,2011,108(2):219-234.
[4] WANG Y,SUN H,SHEN P,et al.Effective inhibition of replication of infectious bursal disease virus by miRNAs delivered by vectors and targeting the VP2 gene[J].Journal of Virological Methods,2010,165(2):127-132.
[5] WU G,QI Y,LIU X,et al.Cecal microRNAome response to Salmonella enterica serovar Enteritidis infection in White Leghorn layer[J].BMC Genomics,2017,18(1):77.
[6] HONG Y H,DINH H,LILLEHOJ H S,et al.Differential regulation of microRNA transcriptome in chicken lines resistant and susceptible to necrotic enteritis disease[J].Poultry Science,2014,93(6):1383-1395.
[7] KIM V N,HAN J,SIOMI M C.Biogenesis of small RNAs in animals[J].Nature Reviews Molecular Cell Biology,2009,10(2):126-139.
[8] LEE Y,JEON K,LEE J T,et al.microRNA maturation:Stepwise processing and subcellular localization[J].The EMBO Journal,2002,21(17):4663-4670.
[9] HAN J,PEDERSEN J S,KWON S C,et al.Posttranscriptional crossregulation between Drosha and DGCR8[J].Cell,2009,136(1):75-84.
[10] GREGORY R I,CHENDRIMADA T P,COOCH N,et al.Human RISC couples microRNA biogenesis and posttranscriptional gene silencing[J].Cell,2005,123(4):631-640.
[11] ZAMORE P D.Ribo-gnome:The big world of small RNAs[J].Science,2005,309(5740):1519-1524.
[12] WANG Y,OUYANG W,PAN Q,et al.Overexpression of microRNA gga-miR-21 in chicken fibroblasts suppresses replication of Infectious bursal disease virus through inhibiting VP1 translation[J].Antiviral Research,2013,100(1):196-201.
[13] FU M,WANG B,CHEN X,et al.microRNA gga-miR-130b suppresses infectious bursal disease virus replication via targeting of the viral genome and cellular suppressors of cytokine signaling 5[J].Journal of Virology,2018,92(1):e01646-17.
[14] FU M J,BIN W,XIANG C,et al.gga-miR-454 suppresses Infectious bursal disease virus (IBDV) replication via directly targeting IBDV genomic segment B and cellular suppressors of cytokine signaling 6 (SOCS6)[J].Virus Research,2018,252:29-40.
[15] DUAN X,ZHAO M,LI X,et al.gga-miR-27b-3p enhances type Ⅰ interferon expression and suppresses infectious Bursal disease virus replication via targeting cellular suppressors of cytokine signaling 3 and 6 (SOCS3 and 6)[J].Virus Research,2020,281:197910.
[16] OUYANG W,WANG Y,MENG K,et al.gga-miR-2127 downregulates the translation of chicken p53 and attenuates chp53-mediated innate immune response against IBDV infection[J].Veterinary Microbiology,2017,198:34-42.
[17] OUYANG W,WANG Y,DU X,et al.gga-miR-9* inhibits IFN production in antiviral innate immunity by targeting interferon regulatory factor 2 to promote IBDV replication[J].Veterinary Microbiology,2015,178(1-2):41-49.
[18] CHEN S,LIAO L Q,ZHAO Q Q,et al.microRNA expression profile in extracellular vesicles derived from ALV-J infected chicken semen[J].Virus Research,2020,286:198083.
[19] ZHAO C,LING X,LI X,et al.microRNA-138-5p inhibits cell migration,invasion and EMT in breast cancer by directly targeting RHBDD1[J].Breast Cancer,2019,26(6):817-825.
[20] ZHU D,GU L,LI Z,et al.miR-138-5p suppresses lung adenocarcinoma cell epithelial-mesenchymal transition,proliferation and metastasis by targeting ZEB2[J].Pathology Research and Practice,2019,215(5):861-872.
[21] FRENQUELLI M,MUZIO M,SCIELZO C,et al.microRNA and proliferation control in chronic lymphocytic leukemia:Functional relationship between miR-221/222 cluster and p27[J].Blood,2010,115(19):3949-3959.
[22] O'CONNELL R M,CHAUDHURI A A,RAO D S,et al.microRNAs enriched in hematopoietic stem cells differentially regulate long-term hematopoietic output[J].Proceedings of the National Academy of Sciences of the United States of America,2010,107(32):14235-14240.
[23] LUO J,SUN A J,TENG M,et al.Expression profiles of microRNAs encoded by the oncogenic Marek's disease virus reveal two distinct expression patterns in vivo during different phases of disease[J].Journal of General Virology,2011,92(3):608-620.
[24] LI H,JI J,XIE Q,et al.Aberrant expression of liver microRNA in chickens infected with subgroup J Avian leukosis virus[J].Virus Research,2012,169(1):268-271.
[25] WANG Q,GAO Y,JI X,et al.Differential expression of microRNAs in avian leukosis virus subgroup J-induced tumors[J].Veterinary Microbiology,2013,162(1):232-238.
[26] LAMBETH L S,YAO Y,SMITH L P,et al.microRNAs 221 and 222 target p27Kip1 in Marek's disease virus-transformed tumour cell line MSB-1[J].Journal of General Virology,2009,90(5):1164-1171.
[27] GAROFALO M,QUINTAVALLE C,ROMANO G,et al.miR221/222 in cancer:Their role in tumor progression and response to therapy[J].Current Molecular Medicine,2012,12(1):27-33.
[28] JI J,XU X,WANG X,et al.Expression of dysregulated miRNA in vivo in DF-1 cells during the course of subgroup J Avian leukosis virus infection[J].Microbial Pathogenesis,2019,126:40-44.
[29] DAI M,FENG M,XIE T,et al.Long non-coding RNA and microRNA profiling provides comprehensive insight into non-coding RNA involved host immune responses in ALV-J-infected chicken primary macrophage[J].Developmental & Comparative Immunology,2019,100:103414.
[30] RYBAK-WOLF A,STOTTMEISTER C,GLAAR P,et al.Circular RNAs in the mammalian brain are highly abundant,conserved,and dynamically expressed[J].Molecular Cell,2015,58(5):870-885.
[31] SONG T F,XU A L,CHEN X H,et al.Circular RNA circRNA_101996 promoted cervical cancer development by regulating miR-1236-3p/TRIM37 axis[J].The Kaohsiung Journal of Medical Sciences,2021,37(7):547-561.
[32] ZHANG M,BAI X,ZENG X,et al.circRNA-miRNA-mRNA in breast cancer[J].Clinica Chimica Acta,2021,523:120-130.
[33] WEI J,LU Y,WANG R,et al.microRNA-375:Potential cancer suppressor and therapeutic drug[J].Bioscience Reports,2021,41(9):BSR20211494.
[34] YAN X,LUO Q,ZHOU S,et al.microRNA-375 reverses the expression of PD-L1 by inactivating the JAK2/STAT3 signaling pathways in gastric cancer[J].Clinics and Research in Hepatology and Gastroenterology,2021,45(5):101574.
[35] DAI H,WANG S,CHEN B,et al.microRNA-375 inhibits the malignant behaviors of hepatic carcinoma cells by targeting NCAPG2[J].Neoplasma,2021,25:210318N358.
[36] LI H,SHANG H,SHU D,et al.gga-miR-375 plays a key role in tumorigenesis post subgroup J Avian leukosis virus infection[J].PLoS One,2014,9(4):e90878.
[37] ZHANG X,YAN Y,LIN W,et al.Circular RNA Vav3 sponges gga-miR-375 to promote epithelial-mesenchymal transition[J].RNA Biology,2019,16(1):118-132.
[38] YU H,XU H,YAN C,et al.gga-miR-148a-5p-targeting PDPK1 inhibits proliferation and cell cycle progression of Avain leukosis virus subgroup J (ALV-J)-infected cells[J].Frontiers in Cell and Developmental Biology,2020,8:587889.
[39] LI Z,LUO Q,XU H,et al.miR-34b-5p suppresses melanoma differentiation-associated gene 5 (MDA5) signaling pathway to promote Avian leukosis virus subgroup J (ALV-J)-infected cells proliferaction and ALV-J replication[J].Frontiers in Cellular and Infection Microbiology,2017,7:17.
[40] LI Z,CHEN B,FENG M,et al.microRNA-23b promotes Avian leukosis virus subgroup J (ALV-J) replication by targeting IRF1[J].Scientific Reports,2015,5(1):10294.
[41] WANG Y,BRAHMAKSHATRIYA V,ZHU H,et al.Identification of differentially expressed miRNAs in chicken lung and trachea with Avian influenza virus infection by a deep sequencing approach[J].BMC Genomics,2009,10:512.
[42] WANG Y,BRAHMAKSHATRIYA V,LUPIANI B,et al.Integrated analysis of microRNA expression and mRNA transcriptome in lungs of Avian influenza virus infected broilers[J].BMC Genomics,2012,13(1):278.
[43] O'DOWD K,EMAM M,EL KHILI M R,et al.Distinct miRNA profile of cellular and extracellular vesicles released from chicken tracheal cells following Avian influenza virus infection[J].Vaccines,2020,8(3):438.
[44] LIN J,XIA J,ZHANG T,et al.Genome-wide profiling of microRNAs reveals novel insights into the interactions between H9N2 Avian influenza virus and avian dendritic cells[J].Oncogene,2018,37(33):4562-4580.
[45] YANG J,HUANG X,LIU Y,et al.Analysis of the microRNA expression profiles of chicken dendritic cells in response to H9N2 Avian influenza virus infection[J].Veterinary Research,2020,51(1):132.
[46] LI P,FAN W,LI Q,et al.Splenic microRNA expression profiles and integration analyses involved in host responses to salmonella enteritidis infection in chickens[J].Frontiers in Cellular and Infection Microbiology,2017,7:377.
[47] JIA X,NIE Q,ZHANG X,et al.Novel microRNA involved in host response to avian pathogenic Escherichia coli identified by deep sequencing and integration analysis[J].Infection and Immunity,2017,85(1):e00688-16.
[48] 宋祥军,邱明宇,蒋胡艳,等.禽致病性大肠杆菌(APEC)感染对雏鸡脾脏miRNA表达谱的影响[J].中国兽医学报,2019,39(12):2373-2379. SONG X J,QIU M Y,JIANG H Y,et al.Effect of APEC infection on miRNA expression profile of chick spleen[J].Chinese Journal of Veterinary Science,2019,39(12):2373-2379.(in Chinese)
[49] LIU X,LIU L,ZHANG M,et al.Chicken cecal microRNAs in the response to Campylobacter jejuni inoculation by Solexa sequencing[J].Poultry Science,2016,95(12):2819-2823.
[50] WANG H,LIU L,LIU X,et al.Correlation between miRNAs and target genes in response to Campylobacter jejuni inoculation in chicken[J].Poultry Science,2018,97(2):485-493.
[51] SUN L,DONG H,ZHANG Z,et al.Activation of epithelial proliferation induced by Eimeria acervulina infection in the duodenum may be associated with cholesterol metabolism[J].Oncotarget,2016,7(19):27627-27640.
[52] LIU T,FAN X,WANG Y,et al.microRNA expression profile of chicken small intestines during Eimeria necatrix infection[J].Poultry Science,2020,99(5):2444-2451.
[53] ZHOU Z,WANG Z,CAO L,et al.Upregulation of chicken TLR4,TLR15 and MyD88 in heterophils and monocyte-derived macrophages stimulated with Eimeria tenella in vitro[J].Experimental Parasitology,2013,133(4):427-433.
[54] KITESSA S M,NATTRASS G S,FORDER R E A,et al.Mucin gene mRNA levels in broilers challenged with Eimeria and/or Clostridium perfringens[J].Avian Diseases,2014,58(3):408-414.
[55] TIM G,VAN LIMBERGEN T,PANAGIOTIS S,et al.Diagnosis of sub-clinical coccidiosis in fast growing broiler chickens by microRNA profiling[J].Genomics,2020,112(5):3218-3225.

Research Progress on Chicken miRNAs and Their Regulation Role After Pathogenic Infection

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