ライフサイエンスコーパス: B. bovis

1 B. bovis reproduces sexually in the midgut of its tick v

2 B. bovis stimulates inducible nitric oxide synthase (iNO

3 B. bovis, an intraerythrocytic protozoal parasite, estab

4 B. bovis-specific T-helper lymphocyte culture supernatan

5 ase treatment of B. bovis extracts abrogated B. bovis-induced proliferation of peripheral blood monon

6 1), which confers partial protection against B. bovis challenge, is recognized by antibodies and T ly

7 recombinant RAP-1 protein responded against B. bovis, but not B. bigemina, merozoites.

8 mmatory mediators by E. coli, T. brucei, and B. bovis DNA was dependent on the presence of unmethylat

9 esia species, (B. bigemina, B. divergens and B. bovis).

10 Cocultures of Mphi and B. bovis-infected erythrocytes either in contact or phys

11 tion was used to explore the ability of anti-B. bovis Ig to interfere with IRBC cytoadhesion, and to

12 Argentina B. bovis strains R1A and S2P have msa-1 genes with amino

13 hat tick passage of the partially attenuated B. bovis T2Bo derivative strain further decreased virule

14 h attenuation, but when retained, attenuated B. bovis can revert to virulence following tick passage.

15 2 locus was characterized from 12 Australian B. bovis strains and isolates, including two vaccine str

16 udy, sequencing of MSA-1 from two Australian B. bovis vaccine strains and 14 breakthrough isolates fr

17 port that monocyte-derived Mphi activated by B. bovis expressed enhanced levels of inflammatory cytok

18 the antiparasitic activity of NO produced by B. bovis-stimulated Mphi has not been definitively demon

19 isms that were mitogenic for murine B cells, B. bovis DNA is largely nonmethylated and induced a dose

20 rier Transform Infrared (ATR-FTIR) to detect B. bovis in red blood cells (RBCs).

21 ites is completely conserved among different B. bovis strains.

22 rved among otherwise antigenically different B. bovis strains.

23 Th-cell epitopes are conserved in different B. bovis strains but not in B. bigemina RAP-1.

24 quencing to 3 Babesia species (B. divergens, B. bovis, and B. bigemina).

25 ynthase mRNA in bovine macrophages by either B. bovis-parasitized erythrocytes and IFN-gamma or CM wa

26 an microscopy to discover new biomarkers for B. bovis infections.

27 Both PCR-based and CF tests for B. bovis had high specificity values ranging from 96 to

28 nsitivities of the three PCR-based tests for B. bovis ranged from 58 to 70% for a single determinatio

29 e in vitro effect of intact and fractionated B. bovis merozoites on bovine macrophage nitric oxide (N

30 gly immunogenic for T helper (Th) cells from B. bovis-immune cattle and that like B-cell epitopes, Th

31 for stimulation of T-cell lines derived from B. bovis-immune cattle.

32 Furthermore, B. bovis and E. coli DNAs enhanced immunoglobulin secret

33 In the presence of IFN-gamma, B. bovis merozoites stimulated NO production, as indicat

34 order E. coli > or = T. cruzi > T. brucei > B. bovis.

35 acted predominantly with spherical bodies in B. bovis merozoites.

36 een antigenic variation and cytoadherence in B. bovis and suggest that the VESA1 Ag acts as an endoth

37 ro model to study the components involved in B. bovis cytoadherence and sequestration.

38 zed culture, we isolated viable and invasive B. bovis merozoites and showed dynamics of merozoite inv

39 The 60-kDa B. bovis RAP-1 is recognized by antibodies and T lymphoc

40 rotection from disease, an in vitro assay of B. bovis sequestration was used to explore the ability o

41 We recently reported that the NT domain of B. bovis RAP-1 contained immunodominant T-cell epitopes,

42 This study evaluated the efficiency of B. bovis infection within Rhipicephalus (Boophilus) micr

43 Furthermore, a lipid fraction of B. bovis-infected erythrocytes stimulated iNOS expressio

44 rine and human B cells, an 11-kb fragment of B. bovis DNA was analyzed for CG dinucleotide content an

45 chemical donors of NO inhibit the growth of B. bovis in vitro.

46 in surface-specific immunoprecipitations of B. bovis-IRBCs.

47 onal factors contribute to the inhibition of B. bovis replication.

48 The results indicate that isolates of B. bovis capable of evading vaccine-induced immunity con

49 the biologically cloned Mexico Mo7 strain of B. bovis and identified the sequence differences between

50 ttle hyperinfected with the Mexico strain of B. bovis and shown to be clinically immune did not cross

51 mmune to challenge with the Mexico strain of B. bovis proliferated against recombinant B. bovis RAP-1

52 SA-2 proteins in the Argentina R1A strain of B. bovis with the Mexico Mo7 clone revealed a relatively

53 le inoculum of a cloned laboratory strain of B. bovis.

54 riant virulent tick-transmissible strains of B. bovis and that R. microplus ticks could acquire and t

55 ico, Texas, Australia, and Israel strains of B. bovis but neither B. bigemina merozoites nor recombin

56 otherwise antigenically different strains of B. bovis, supports the inclusion of this region in vacci

57 cribed babr 0.8 gene in Australia strains of B. bovis.

58 ompared AlphaFold2-predicted 3D structure of B. bovis HAP2 with the well-characterized crystal struct

59 DNase treatment of B. bovis extracts abrogated B. bovis-induced proliferati

60 ant erythrocyte surface antigen 1 (VESA1) of B. bovis IRBCs.

61 erythrocytes but not on either uninfected or B. bovis-parasitized erythrocytes.

62 mine whether DNA from the protozan parasites B. bovis, Trypanosoma cruzi, and T. brucei activates mac

63 While both inhibitors were able to prevent B. bovis egress from RBC and increased percentage of bin

64 of B. bovis proliferated against recombinant B. bovis RAP-1 protein derived from the Mexico strain.

65 Sequencing analysis of select B. bovis genes before and after tick passage showed sign

66 sults indicate the potential to use selected B. bovis RAP-1 peptides as immunogens to prime for stron

67 dy the components involved in sequestration, B. bovis parasites that induce adhesion of the infected

68 d that immunization of cattle with full size B. bovis HAP2 blocks transmission of the parasite by Rhi

69 in independent populations of Babesia spp. (B. bovis and B. divergens).

70 t B. bovis merozoites and antigen-stimulated B. bovis-immune T cells can induce the production of NO,

71 These findings demonstrate that B. bovis induces an innate immune response that is capab

72 The studies reported here demonstrate that B. bovis RAP-1 is strongly immunogenic for T helper (Th)

73 These results show that B. bovis merozoites and antigen-stimulated B. bovis-immu

74 It was previously shown that B. bovis RAP-1 associates with the merozoite surface as

75 es, fusion loops, and disulfide bonds in the B. bovis HAP2.

76 Ag acts as an endothelial cell ligand on the B. bovis-IRBC.

77 ns using sera from animals infected with the B. bovis vaccine strains.

78 CD4(+)-T-cell lines from three B. bovis-immune cattle with different DRB3 haplotypes re

79 ive type 1 immune responses upon exposure to B. bovis.

80 tory for T lymphocytes from cattle immune to B. bovis.

81 The lack of response to B. bovis RAP-1 indicated that a strictly conserved 14-am

82 r, NO produced by bovine Mphi in response to B. bovis-infected erythrocytes was only partially respon

83 nfection rates of 22% to 30% and transmitted B. bovis during transmission feeding.

84 ufficient to protect calves against virulent B. bovis challenge.

85 t both calves and ticks can support virulent B. bovis coinfection through all phases of the hemoparas

86 by repeated stimulation of lymphocytes with B. bovis membrane antigen proliferated strongly against