Seroreactive Mycobacterial Proteins and Lipid in Cattle with Bovine Tuberculosis

Haet Sal Jeon; A-Rum Shin; Yeo-Jin Son; Jae-Myung Kim; Yunho Jang; Suk Kim; Kang-In Lee; Chul Hee Choi; Jeong-Kyu Park; Hwa-Jung Kim

doi:10.4167/jbv.2015.45.2.112

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Jeon, Shin, Son, Kim, Jang, Kim, Lee, Choi, Park, and Kim: Seroreactive Mycobacterial Proteins and Lipid in Cattle with Bovine Tuberculosis

Original Article

J Bacteriol Virol 2015;45(2):112-125.

Published online: 9 February 2015

DOI: https://doi.org/10.4167/jbv.2015.45.2.112

Seroreactive Mycobacterial Proteins and Lipid in Cattle with Bovine Tuberculosis

Haet Sal Jeon¹, A-Rum Shin¹, Yeo-Jin Son¹, Jae-Myung Kim², Yunho Jang², Suk Kim³, Kang-In Lee¹, Chul Hee Choi¹, Jeong-Kyu Park¹, Hwa-Jung Kim^1,^∗

¹Department of Microbiology and Research Institute for Medical Sciences, College of Medicine, Chungnam National University, Daejeon, Korea

²Bacteriology Disease Division, Animal and Plant Quarantine Agency, Anyang, Gyeonggido, Korea

³Institute of Animal Medicine, College of Veterinary Medicine, Gyeongsang National University, Jinju, Korea

^∗Corresponding author: Hwa-Jung Kim. Department of Microbiology, College of Medicine, Chungnam National University, 6 Munwha-Dong, Jung-Ku, Daejeon, 301-747, Korea. Phone: +82-42-580-8242, Fax: +82-42-585-3686, e-mail: hjukim@cnu.ac.kr

^∗∗ This study was financially supported by the Animal and Plant Quarantine Agency (Z-1541778-2012-13-01), Ministry of Agriculture, Food and Rural Affairs, Republic of Korea.

Received 7 April 20154 May 2015 Accepted 7 May 2015

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Bovine tuberculosis caused by Mycobacterium bovis is a major economic problem in several countries. Antibody responses are useful indicators of M. bovis infection of cattle. To overcome drawback of serological tests with low sensitivity, identification and characterization of multiple serodiagnostic antigens has been required. In this study, the antigens with strong antibody reactivity were searched using fractionation of M. bovis culture filtrate proteins and probing with sera from M. bovis-infected cattle. Twelve proteins which have not previously been described as serologic targets were identified and six proteins among them were expressed in Escherichia coli. The mycobacterial lipoarabinomannan (LAM) with strong seroreactivity in cattle was identified and purified. IgG and IgA responses against the newly identified proteins, the seroreactive proteins with strong antibody reactivity in human tuberculosis, and LAM were compared in M. bovis-infected and non-infected cattle as well as in field samples. In general, sensitivity of the tested antigens was higher in M. bovis-infected cattle than purified protein derivative (PPD) (+) field samples. Although a diverse reactivity and sensitivity according to the antigens were shown, the diagnostic utility of both IgA and IgG antibody to the antigens was similar in M. bovis-infected cattle but utility of IgG antibody was superior to that of IgA in field samples. The antigen with the highest diagnostic value was LAM in both the groups. Other antigens with considerable diagnostic utility were BCG_3488c, BCG_2330, Antigen 85, HspX, and Rv3593 when considered the sensitivity and area under the receiver characteristic curve (AUC) value. These antigens may be valuable candidates to be included in a cocktail test kit for bovine tuberculosis diagnosis.

Keywords: Bovine tuberculosis, Antibody response, Recombinant protein, Lipoarabinomannan

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Figure 1.

SDS-PAGE analysis of the fractionation of Mycobacterium bovis culture filtrate proteins (CFPs). The 0~80% or 50~80% ammonium sulfate precipitate (ASP) of M. bovis AN5 total CFPs (lane 1) was fractionated into a pass fraction, 50 mM potassium phosphate buffer (kPB) eluate, and 1 mM kPB eluate by hydrophobic interaction chromatography (HIC). Three fractions were separated into a pass fraction and 500 mM kPB eluate by hydroxylapatite (HAT) chromatography, and then if necessary, further fractionated by diethylaminoethanol (DEAE) ion exchange chromatography. Total CFPs → 0~80% ASP (lane 2), total CFPs → 0~80% ASP → HIC pass (lane 3), total CFPs → 0~80% ASP → HIC 50 mM (lane 4), total CFPs → 0~80% ASP → HIC 1 mM (lane 5), total CFPs → 0~80% ASP → HIC pass → HAT pass (lane 6), M. bovis BCG total CFPs → 50~80% ASP → HAT pass → DAEA 51~66 (lane 7). The gel was stained with Coomassie blue.

Figure 2.

2-DE and immunoblot analysis of fractionated culture filtrate proteins (CFPs). The fractions were separated by isoelectric focusing using a 7 cm pH gradient strip (pH 4 to 7) in the first dimension, and 15% SDS-PAGE in the second dimension. M. bovis AN5 total CFPs → 0~80% ASP → HIC pass → HAT pass (A), total CFPs → 0~80% ASP → HIC pass (B), total CFPs → 0~80% ASP (C), total CFPs → 0~80% ASP → HIC 50 mM (D), total CFPs → 0~80% ASP → HIC 1 mM (E) and M. bovis BCG total CFPs →50~80% ASP → HAT pass → DAEA 51~66 (F). The gels were analyzed by Coomassie blue stain and immunoblot with M. bovis-infected sera.

Figure 3.

SDS-PAGE analysis of purified proteins. BCG_0389 (A), BCG_1909 (B), BCG_2330 (C), BCG_2765 (D), BCG_3488c (E) and BCG_3706c (F) proteins were overexpressed in Escherichia coli, purified by Ni-NTA affinity chromatography, and analyzed by SDS-PAGE with Coomassie blue staining.

Figure 4.

SDS-PAGE analysis of purified proteins with diagnostic utility in human tuberculosis. The purified recombinant proteins of Rv3593 (A), Rv1605 (B), MAV5183 (C) and MAV4300(D) were subjected to SDS-PAGE and stained with Coomassie blue.

Figure 5.

Antibody reactivity and purification of lipoarabinomannan (LAM). (A) The M. bovis CFPs was analyzed with Coomassie blue (CB) staining and immunoblot using M. bovis-infected cattle sera. (B) LAM from total lipid extract of M. tuberculosis was purified by Triton-X 114 phase partitioning, separated by SDS-PAGE, and then analyzed with silver staining and immunoblot using sera of M. bovis-infected (lane 1) or M. avium-infected cattle (lane 2). LM, lipomannan.

Table 1.

Primers sets for genes amplified by polymerase chain reaction (PCR)

Protein	Primer sequences (5′ – 3′)	Restriction site used
BCG_0389	5′ CATATGGCTCGTGCGGTCGGGATCGAC 3′	Nde I
BCG_0389	5′ AAGCTTCTTGGCCTCCCGGCCGTCGTC 3′	Hind III
BCG_1909	5′ CATATGAAGTCAGCAAGCGACCCGTTC 3′	Nde I
BCG_1909	5′ AAGCTTTGTGACCGCCAGTAATGCCAC 3′	Hind III
BCG_2330	5′ CATATGGCCACCAGTAGCGACGACATC 3′	Nde I
BCG_2330	5′ AAGCTTTGGGCCGACAGGAAGCTCAGC 3′	Hind III
BCG_2765	5′ CATATGCCCGTCGTCGTCGTCGCCACG 3′	Nde I
BCG_2765	5′ AAGCTTCCGGCGCAGCTGCCCTTTGCT 3′	Hind III
BCG_3488c	5′ CATATGGCGAAGGTGAACATCAAGCCA 3′	Nde I
BCG_3488c	5′ AAGCTTCTTGGAAACGACGGCCAGCAC 3′	Hind III
Rv1605	5′ GGGCCCCATATGTATGCCGACCGTGACCTTCCGGGG 3′	Nde I
Rv1605	5′ GGGCCCAAGCTTTCGCACGGTGATTCCTTCCGCGGC 3′	Hind III
Rv3593	5′ CGCCATATGAATCACGGGCACCGGATCGAC 3′	Nde I
Rv3593	5′ CCCAAGCTTTTGTGGCGCTATCAACGCAAAG 3′	Hind III
MAV5183	5′ CATATGTCCAAGCCGGGG CTTCCGGTG 3′	Nde I
MAV5183	5′ AAGCTTGGTGGCGGGCTGGGCGGGTTG 3′	Hind III
MAV4300	5′ GGGCCCCATATGTCTGTCGAGCCGGACGTCGAA 3′	Nde I
MAV4300	5′ GGGCCCCTCGAGGCGGGAGAACATGATGGCGCG 3′	Xho I

Table 2.

Identification of Mycobacterium bovis seroreactive proteins by liquid chromatography-electrospray ionization-mass spectrometry (LC-ESI-MS)

Spot No.	Protein	Mass (kDa)	pI	Amino acid (aa)	Locus tag
J1	Conserved hypothetical protein	31.567	11.92	288	BCG_3953c
J2	Possible transposase	25.021	11.39	225	BCG_3456
J3	Probable transposase (fragment)	23.975	11.41	228	BCG_1093c
J4	Hypothetical protein BCG_2330	10.598	9.35	95	BCG_2330
J5	Conserved hypothetical protein	16.207	7.79	145	BCG_1909
J6	Putative conserved lipoprotein lpqU	25.983	6.96	243	BCG_1079
J7, 8, 9	Secreted antigen 85A precursor	35.686	6.1	338	BCG_3866c
J10	Conserved hypothetical protein	69.775	4.7	677	BCG_1871c
J11	Probable chaperone protein dnaK	66.83	4.85	625	BCG_0389
J12	Probable membrane protein	23.116	6.81	209	BCG_2817
J13	Chain A, crystal structure of cpn10, GroES	10.667	4.6	100	BCG_3488c
J14	Cold shock protein A	7.336	5.2	67	BCG_3706c
J15	Hypothetical protein Rv2749	11.149	5.2	104	BCG_2765

Table 3.

IgG antibody responses to each antigen in sera from Mycobacterium bovis-infected cattle and non-infected cattle^a

Antigens	Groups (n=60)
	M. bovis-infected cattle (n=30)			Non-infected cattle (n=30)
	Mean OD ± SD	% sensitivity (no. of positive samples)	AUC (μg · h/ml) (95% CI)	P value^b	Mean OD ± SD	% specificity (no. of positive samples)
BCG_0389	0.0218±0.0206	23.3 (7)	0.6422 (0.5007~0.7838)	0.0585	0.0124±0.0132	90.0 (3)
BCG_2330	0.1664±0.0657	3.3 (1)	0.6289 (0.4854~0.7724)	0.0864	0.1252±0.092	100.0 (0)
BCG_2765	0.0021±0.0129	16.7 (5)	0.6778 (0.5395~0.8160)	0.018	0.0001±0.0094	96.7 (1)
BCG_3488c	0.0065±0.0102	3.3 (1)	0.7489 (0.6226~0.8752)	0.0009	0.0018±0.012	96.7 (1)
Ag85	0.0738±0.2035	53.3 (16)	0.8450 (0.7487~0.9413)	<0.0001	0.0002±0.0058	96.7 (1)
HspX	0.0613±0.2137	26.7 (8)	0.7711 (0.6531~0.8891)	0.0003	0.0061±0.0082	93.3 (2)
CysA	0.0137±0.0129	40.0 (12)	0.8689 (0.7764~0.9613)	<0.0001	0.0017±0.0057	96.7 (1)
Rv1605	0.0076±0.0133	30.0 (9)	0.7294 (0.5980~0.8609)	0.0023	0.0002±0.0054	96.7 (1)
Rv3593	0.0229±0.0538	33.3 (10)	0.7206 (0.5895~0.8516)	0.0034	0.003±0.0059	96.7 (1)
MAV5183	0.2726±0.2444	6.7 (2)	0.6178 (0.4736~0.7620)	0.1171	0.3199±0.1582	100.0 (0)
MAV4300	0.0365±0.0351	10.0 (3)	0.5550 (0.4072~0.7028)	0.4643	0.0306±0.0278	93.3 (2)
LAM	0.2118±0.2713	90.0 (27)	0.9600 (00.9051~1.015)	<0.0001	0.0105±0.007	96.7 (1)

^a The cut-off value for each antigen was calculated as mean optical density (OD) plus two standard deviations (SD) obtained with sera from cattle known to be non-infected with M. bovis. AUC = area under the receiver characteristic curve; CI = confidence interval.

^b Mann-Whitney test was used to determine differences between two groups for each antigen.

Table 4.

IgA antibody responses to each antigen in sera from Mycobacterium bovis-infected cattle and non-infected cattle^a

Antigens	Groups (n=60)
	M. bovis-infected cattle (n=30)				Non-infected cattle (n=30)
	Mean OD ± SD	% sensitivity (no. of positive samples)	AUC (μg · h/ml) (95% CI)	P value^b	Mean OD ± SD	% specificity (no. of positive samples)
BCG_0389	0.1447±0.2052	20.0 (6)	0.6889 (0.5542~0.8235)	0.012	0.0735±0.0448	96.7 (1)
BCG_2330	0.0722±0.2118	33.3 (10)	0.7833 (0.6704~0.8963)	0.0002	0.012±0.0105	96.7 (1)
BCG_2765	0.0625±0.0686	20.0 (6)	0.6272 (0.4852~0.7692)	0.0906	0.0331±0.0344	96.7 (1)
BCG_3488c	0.0792±0.2108	50.0 (15)	0.7856 (0.6702~0.9009)	0.0001	0.0149±0.0098	100.0 (0)
Ag85	0.0808±0.2209	40.0 (12)	0.7767 (0.6578~0.8956)	0.0002	0.0075±0.0102	93.3 (2)
HspX	0.0252±0.0225	10.0 (3)	0.6672 (0.5281~0.8063)	0.0261	0.0161±0.0209	90.0 (3)
CysA	0.0083±0.0263	10.0 (3)	0.7189 (0.5841~0.8537)	0.0036	0.0001±0.0213	96.7 (1)
Rv1605	0.0973±0.2102	36.7 (11)	0.7767 (0.6610~0.8923)	0.0002	0.0233±0.0166	100.0 (0)
Rv3593	0.0507±0.041	40.0 (12)	0.7883 (0.6759~0.9007)	0.0001	0.0192±0.0137	96.7 (1)
MAV5183	0.2564±0.2707	20.0 (6)	0.5633 (0.4160~0.7107)	0.3994	0.1774±0.0881	96.7 (1)
MAV4300	0.1079±0.2081	30.0 (9)	0.7667 (0.6485~0.8849)	0.0004	0.0286±0.0349	96.7 (1)
LAM	0.2164±0.3078	60.0 (18)	0.8856 (0.8032~0.9679)	<0.0001	0.0247±0.0213	93.3 (2)

^b Mann-Whitney test was used to determine differences between two groups for each antigen.

Table 5.

IgG antibody responses to each antigen in field samples^a

Antigens	Group (n=155)
	PPD (+) cattle (n=59)				PD (-) cattle (n=96)
	P Mean OD ± SD	% sensitivity (no. of positive samples)	AUC (μg · h/ml) (95% CI)	P value^b	P Mean OD ± SD	% specificity (no. of positive samples)
BCG_0389	0.0253±0.0258	5.1 (3)	0.5280 (0.4277~0.6284)	0.56	0.0225±0.0224	96.9 (3)
BCG_2330	0.0806±0.0648	18.6 (11)	0.6245 (0.5316~0.7174)	0.0097	0.0514±0.0448	95.8 (4)
BCG_2765	0.0033±0.061	0.0 (0)	0.5580 (0.4444~0.6715)	0.2282	0.0021±0.0307	99.0 (1)
BCG_3488c	0.0191±0.0197	55.9 (33)	0.6956 (0.5989~0.7924)	<0.0001	0.0026±0.0073	95.8 (4)
Ag85	0.0072±0.014	13.6 (8)	0.6724 0.5867~0.7581)	0.0003	0.0011±0.0088	94.8 (5)
HspX	0.049±0.2823	10.2 (6)	0.5927 (0.5039~0.6815)	0.0531	0.0099±0.0152	95.8 (4)
CysA	0.0077±0.0062	1.7 (1)	0.7071 (0.6263~0.7879)	<0.0001	0.0042±0.0113	96.9 (3)
Rv1605	0.0034±0.0061	0.0 (0)	0.6326 (0.5454~0.7198)	0.0057	0.0086±0.0114	93.7 (6)
Rv3593	0.0025±0.0092	8.5 (5)	0.5535 (0.4608~0.6462)	0.2665	0.0028±0.0068	96.9 (3)
MAV5183	0.4782±0.425	33.9 (20)	0.6613 (0.5597~0.7629)	0.0008	0.2652±0.2073	94.8 (5)
MAV4300	0.0326±0.03	8.5 (5)	0.5767 (0.4849~0.6685)	0.1108	0.0262±0.0271	94.8 (5)
LAM	0.2129±0.2007	71.2 (42)	0.9328 (0.8915~0.9740)	<0.0001	0.019±0.0206	96.9 (3)

^a The cut-off value for each antigen was calculated as mean optical density (OD) plus two standard deviations (SD) obtained with sera from purified protein derivative (PPD) (-) cattle. AUC = area under the receiver characteristic curve; CI = confidence interval.

^b Mann-Whitney test was used to determine differences between two groups for each antigen.

Table 6.

IgA antibody responses to each antigen in field samples^a

Antigens	Group (n=155)
	PPD (+) cattle (n=59)				PPD (-) cattle (n=96)
	Mean OD ± SD	% sensitivity (no. of positive samples)	AUC (μg · h/ml) (95% CI)	P value^b	Mean OD ± SD	% specificity (no. of positive samples)
BCG_0389	0.0961±0.2789	13.6 (8)	0.5717 (0.4760~0.6673)	0.1347	0.0685±0.0398	93.7 (6)
BCG_2330	0.0547±0.2815	6.8 (4)	0.6705 (0.5870~0.7539)	0.0004	0.0117±0.0158	95.8 (4)
BCG_2765	0.0592±0.0393	3.4 (2)	0.5395 (0.4470~0.6319)	0.4102	0.0565±0.0458	97.9 (2)
BCG_3488c	0.0629±0.2816	3.4 (2)	0.5200 (0.4286~0.6113)	0.6771	0.0285±0.0302	91.7 (8)
Ag85	0.0562±0.2816	6.8 (4)	0.5640 (0.4733~0.6547)	0.1816	0.0175±0.0208	94.8 (5)
HspX	0.0201±0.0165	3.4 (2)	0.5200 (0.4257~0.6144)	0.6758	0.0223±0.0186	95.8 (4)
CysA	0.006±0.0325	1.7 (1)	0.5560 (0.4610~0.6509)	0.2445	0.0126±0.0392	95.8 (4)
Rv1605	0.0817±0.2792	1.7 (1)	0.5514 (0.4574~0.6453)	0.2836	0.0532±0.036	96.9 (3)
Rv3593	0.04±0.0299	5.1 (3)	0.6312 (0.5369~0.7255)	0.0062	0.0511±0.0332	95.8 (4)
MAV5183	0.12±0.1248	1.7 (1)	0.5672 (0.4735~0.6608)	0.1627	0.1755±0.229	95.8 (4)
MAV4300	0.1026±0.2809	3.4 (2)	0.5245 (0.4279~0.6210)	0.6098	0.0779±0.0695	96.9 (3)
LAM	0.2026±0.3073	49.2 (29)	0.8397 (0.7694~0.9100)	<0.0001	0.0372±0.0339	97.9 (2)

^b Mann-Whitney test was used to determine differences between two groups for each antigen.

Table 7.

Effect of antigen combination to increase the sensitivity

Ag combination	M. bovis-infected /non-infected cattle
Ag combination	Sensitivity % positive sera) (No. of	Specificity % (No. of positive sera)
IgG
LAM only	90.0 (27)	96.7 (1)
LAM + Ag85	93.3 (28)	93.3 (2)
IgA
LAM only	60.0 (18)	93.3 (2)
LAM + BCG_3488c	70.0 (21)	93.3 (2)

Ag Combination	PPD (+) and (-) field sample
Ag Combination	Sensitivity % (No. of positive sera)	Specificity % (No. of positive sera)
IgG
LAM only	71.2 (42)	96.9 (3)
LAM + BCG_3488c	84.7 (50)	93.7 (6)
IgA
LAM only	49.2 (29)	97.9 (2)
LAM + Ag85	50.8 (30)	94.8 (5)

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