«Previous Article|Table of Contents|Next Article»

¡¶ÄϾ©Ê¦´óѧ±¨£¨×ÔÈ»¿Æѧ°æ£©¡·[ISSN:1001-4616/CN:32-1239/N]

Issue:

2021Äê04ÆÚ

Page:

43-52

Research Field:

¡¤ÉúÎïѧ¡¤

Publishing date:

Info

Title:

Research on TLR8 Gene Immune Response Function of BottlenoseDolphins(Tursiops truncatus)and Cattle(Bos taurus)

Author(s):

Gu Long; Zhang Weijing; Yu Fangfang; Ren Wenhua

School of Life Sciences,Nanjing Normal University,Nanjing 210023,China

Keywords:

Tursiops truncatus; Bos taurus; TLR8; NF-¦ÊB; IL-8

PACS:

Q594

DOI:

10.3969/j.issn.1001-4616.2021.04.006

Abstract:

Cetaceans are the descendants of terrestrial mammals. They transitioned from land to ocean about 56 million years ago. The autoimmune function of cetaceans evolved to meet the challenges of marine pathogens. TLR8 gene is a member of the viral Toll-like receptor family. It activates downstream signal pathways after being induced by pathogens,and plays an important role in regulating the body¡¯s immunity against pathogen infection. In this study,we analyzed the structure of the TLR8 gene of the bottlenose dolphin(Tursiops truncatus)and cattle(Bos taurus),cloned the TLR8 gene and constructed a recombinant plasmid to transfect the human embryonic kidney cell line HEK293 cells,and then stimulated the TLR8 synthetic agonist R848 Cells,to detect the differences in the expression of NF-¦ÊB and IL-8 downstream of the TLR8 signaling pathway. The experimental results showed that the expression levels of NF-¦ÊB and IL-8 of the two species were significantly higher than those of the empty vector transfection group,while the expression levels of bottlenose dolphins were lower than those of cattle. It is speculated that the TLR8 gene exerts an immune function in response to heterologous stimuli. In order to adapt to the marine environment different from the terrestrial environment,cetaceans have adopted different coping strategies and models from terrestrial animals.

References:

[1] THEWISSEN J G M,COOPER L N,CLEMENTZ M T,et al. Whales originated from aquatic artiodactyls in the Eocene epoch of India[J]. Nature,2007,450(7173):1190-1194.
[2]MCCALLUM H,HARVELL D,DOBSON A. Rates of spread of marine pathogens[J]. Ecology letters,2003,6(12):1062-1067.
[3]BEINEKE A,SIEBERT U,WOHLSEIN P,et al. Immunology of whales and dolphins[J]. Veterinary immunology & immunopathology,2010,133(2-4):81-94.
[4]XU S,REN W,ZHOU X,et al. Sequence polymorphism and geographical variation at a positively selected MHC-DRB gene in the finless porpoise(Neophocaena phocaenoides):implication for recent differentiation of the Yangtze Finless porpoise?[J]. Journal of molecular evolution,2010,71(1):6-22.
[5]GUI D,JIA K,XIA J,et al. De novo assembly of the Indo-Pacific humpback dolphin leucocyte transcriptome to identify putative genes involved in the aquatic adaptation and immune response[J]. PLoS one,2013,8(8):e72417.
[6]SHEN T,XU S,WANG X,et al. Adaptive evolution and functional constraint at TLR4 during the secondary aquatic adaptation and diversification of cetaceans[J]. BMC evolutionary biology,2012,12(1):39.
[7]TIAN R,CHEN M,CHAI S,et al. Divergent selection of pattern recognition receptors in mammals with different ecological characteristics[J]. Journal of molecular evolution,2018,86(2):138-149.
[8]XU S,TIAN R,LIN Y,et al. Widespread positive selection on cetacean TLR extracellular domain[J]. Molecular immunology,2019,106:135-142.
[9]TIAN R,SEIM I,ZHANG Z,et al. Distinct evolution of toll-like receptor signaling pathway genes in cetaceans[J]. Genes & genomics,2019,41(12):1417-1430.
[10]TAKEDA K,AKIRA S. TLR signaling pathways.[J]. Seminars in immunology,2004,16(1):3-9.
[11]ROACH J C,GLUSMAN G,ROWEN L,et al. The evolution of vertebrate Toll-like receptors[J]. Proceedings of the national academy of sciences,2005,102(27):9577-9582.
[12]TEMPERLEY N D,BERLIN S,PATON I R,et al. Evolution of the chicken Toll-like receptor gene family:a story of gene gain and gene loss[J]. BMC genomics,2008,9(1):62.
[13]·ëÔÃ,ÏÄѩɽ. ²¡¶¾Ïà¹ØTollÑùÊÜÌåÑо¿½øÕ¹[J]. ÏÖ´úÃâÒßѧ,2007,27(5):434-438.
[14]ROACH J C,GLUSMAN G,ROWEN L,et al. The evolution of vertebrate Toll-like receptors[J]. Proceedings of the national academy of sciences,2005,102(27):9577-9582.
[15]IWASAKI A,MEDZHITOV R. Toll-like receptor control of the adaptive immune responses[J]. Nature immunology,2004,5(10):987-995.
[16]O¡¯NEILL L A J,BOWIE A G. The family of five:TIR-domain-containing adaptors in Toll-like receptor signalling[J]. Nature reviews immunology,2007,7(5):353-364.
[17]HERBERHOLD S,COCH C,ZILLINGER T,et al. Delivery with polycations extends the immunostimulant Ribomunyl¡k into a potent antiviral Toll-like receptor 7/8 agonist[J]. Antiviral therapy,2011,16(5):751.
[18]GAY N J,GANGLOFF M. Structure and function of Toll receptors and their ligands[J]. Annual review of biochemistry,2007,76:141-165.
[19]XU S,TIAN R,LIN Y,et al. Widespread positive selection on cetacean TLR extracellular domain[J]. Molecular immunology,2019,106:135-142.
[20]TAKEUCHI O,AKIRA S. Recognition of viruses by innate immunity[J]. Immunological reviews,2007,220(1):214-224.
[21]MUKHERJEE S,SARKAR R N,WAGENER D K,et al. Signatures of natural selection are not uniform across genes of innate immune system,but purifying selection is the dominant signature[J]. Proceedings of the national academy of sciences,2009,106(17):7073-7078.
[22]BARREIRO L B,BEN-ALI M,QUACH H,et al. Evolutionary dynamics of human Toll-like receptors and their different contributions to host defense[J]. PLoS genetics,2009,5(7):e1000562.
[23]SHEN T,XU S,WANG X,et al. Adaptive evolution and functional constraint at TLR4 during the secondary aquatic adaptation and diversification of cetaceans[J]. BMC evolutionary biology,2012,12(1):39.
[24]NAKAJIMA T,OHTANI H,SATTA Y,et al. Natural selection in the TLR-related genes in the course of primate evolution[J]. Immunogenetics,2008,60(12):727-735.
[25]BELL J K,MULLEN G E,LEIFER C A,et al. Leucine-rich repeats and pathogen recognition in Toll-like receptors[J]. Trends in immunology,2003,24(10):528-533.
[26]FORSBACH A,NEMORIN J G,MONTINO C,et al. Identification of RNA sequence motifs stimulating sequence-specific TLR8-dependent immune responses[J]. The journal of immunology,2008,180(6):3729-3738.
[27]ZHOU Z,SUN L. Immune effects of R848:evidences that suggest an essential role of TLR7/8-induced,Myd88- and NF-¦ÊB-dependent signaling in the antiviral immunity of Japanese flounder(Paralichthys olivaceus)[J]. Developmental & comparative immunology,2015,49(1):113-120.
[28]HACKSTEIN H,KNOCHE A,NOCKHER A,et al. The TLR7/8 ligand resiquimod targets monocyte-derived dendritic cell differentiation via TLR8 and augments functional dendritic cell generation[J]. Cellular immunology,2011,271(2):401-412.
[29]LIU J,XU C,HSU L C,et al. A five-amino-acid motif in the undefined region of the TLR8 ectodomain is required for species-specific ligand recognition[J]. Molecular immunology,2010,47(5):1083-1090.
[30]GORDEN K K B,QIU X X,BINSFELD C C A,et al. Cutting edge:activation of murine TLR8 by a combination of imidazoquinoline immune response modifiers and polyT oligodeoxynucleotides[J]. The journal of immunology,2006,177(10):6584-6587.
[31]HEMMI H,KAISHO T,TAKEUCHI O,et al. Small anti-viral compounds activate immune cells via the TLR7 MyD88-dependent signaling pathway[J]. Nature immunology,2002,3(2):196-200.
[32]WANG Z,CHEN Z,XU S,et al. ¡®Obesity¡¯is healthy for cetaceans?Evidence from pervasive positive selection in genes related to triacylglycerol metabolism[J]. Scientific reports,2015,5:14187.
[33]FUHRMAN J A. Marine viruses and their biogeochemical and ecological effects[J]. Nature,1999,399(6736):541-548.
[34]JIANG S,STEWARD G,JELLISON R,et al. Abundance,distribution,and diversity of viruses in alkaline,hypersaline Mono Lake,California[J]. Microbial ecology,2004,47(1):9-17.
[35]WOMMACK K E,COLWELL R R. Virioplankton:viruses in aquatic ecosystems[J]. Microbiology and molecular biology reviews,2000,64(1):69-114.
[36]MANTOVANI M,RUSCHEL A R,PUCHALSKI A,et al. Diversity of species and successional structure of a secondary formation in an Atlantic rain forest[J]. Scientia forestalis(Brazil),2005,(67):141-142.
[37]SUTTLE C A. Marine viruses¡ªmajor players in the global ecosystem[J]. Nature reviews microbiology,2007,5(10):801-812.
[38]WEITZ J S,WILHELM S W. Ocean viruses and their effects on microbial communities and biogeochemical cycles[J]. F1000 biology reports,2012,4:17.

Memo

Memo:

-

Common functions

Last Update: 2021-12-15