免疫pcr在结核病血清诊断中的作用

P. Mehta
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Polymerase chain reaction (PCR) tests targeting IS6110, mpb64 (Rv1980c), pstS1 (Rv0934), etc. are widely used for the diagnosis of TB patients [2] however PCR can’t detect non nucleic acid molecules such as proteins, lipids and carbohydrates, which are abundant in circulation during TB infection. Though enzyme-linked immunosorbent assay (ELISA) is widely used for the detection of proteins, but it fails when there is a low concentration of target proteins in body fluids of TB patients [3] and it also leads to nonspecific binding of body fluids that ultimately leads to reduced specificity. Several commercial antibody detection tests are available with imprecise, inconsistent and invariable results by ELISA, therefore, the WHO has recommended against the use of these tests [4] whereas direct detection of Mycobacterium tuberculosis antigens allow specific diagnosis of active TB independent of the host’s immune response [5]. Considering that antigen detection may be translated into a rapid POC TB diagnostic test, technology to improve their detection is urgently needed. Originally discovered by [6] immuno-PCR (I-PCR) combines the versatility and simplicity of ELISA with the enormous amplification capacity of PCR, which has been used for the ultralow detection of cytokines, protooncogenes and potential biomarkers for an early diagnosis of infectious and non-infectious diseases including TB infection [2] and that showed several-fold lower detection limit than analogous ELISA. We could detect up to 1femtogram (fg)/mL of mycobacterial recombinant purified protein such as early secreted antigenic target-6 (ESAT-6, Rv3875) and immunodominant antigen 85B (Ag85B, Rv1886c) and up to 10 fg/mL of cord factor (trehalos-6,6’dimycolate) by I-PCR, which was atleast 105-fold lower than ELISA [7,8]. We previously developed I-PCR based on streptavidin-biotin system for the detection of cocktail of regions of differences (RD) encoded proteins of M. tuberculosis such as ESAT-6, culture filtrate protein-10 (CFP-10, Rv3874), CFP-21 (Rv1984c) etc. [2]. Furthermore, by paired sample analysis, i.e., the detection of cocktail of RD proteins in sputum and detection of anti-RD antibodies in serum of the same PTB patients by I-PCR exhibited higher sensitivities (91% in smearpositive PTB cases and 72% in smear-negative PTB cases) and specificities (85%). We recently developed I-PCR based on succinimidyl 4-[N-maleimidomethyl]-cyclohexane-1carboxylate (SMCC) for the detection of Ag85B, ESAT-6, cord factor and the cocktail of these antigens in body fluids of PTB and extrapulmonary TB (EPTB) patients. Strikingly, detection of Ag85B protein in sputum samples of PTB patients by I-PCR exhibited better sensitivity (80-83% in PTB patients and 66.6-68.6% in EPTB patients) and specificity (90.3-92.8% in PTB patients and 90-92% in EPTB patients) than the detection of cocktail of Ag85B, ESAT-6 and cord factor [7,8] which was also superior to ELISA. I-PCR based on SMCC is quicker to perform due to less incubation/wash steps and lead to reduced background signals. The humoral antibody responses to different M. tuberculosis antigens in TB patients are heterogeneous. Therefore, the detection of cocktail of anti-Ag85B, anti-ESAT-6 and anti-cord factor antibodies in sera of TB patients was performed by I-PCR, which was superior (84.1% and 77.5% sensitivity and 90.9% and 92% specificity in PTB and EPTB patients, respectively) to ELISA as well as to the detection of individual antibodies by I-PCR [9]. Interestingly [10] used seventeen M. tuberculosis antigens for antibody response by ELISA, the sensitivity with individual antigens to detect the antibody response ranged from 55.782.9% with the specificity ranging from 62 to 92.2%, whereas the sensitivity reached 69.5% with a specificity of 91.1% with five optimal antigens (Lipoarabinomannan, 38 kDa, KatG, 16 kDa, MPT63 or Mtb39). We observed only few false positive results in controls with I-PCR assays based on both antigen and antibody detection thus leading to high specificity, which could be due to proper washing at each step and the use of appropriate blocking solutions. The identification of few false positive results also suggests that I-PCR assay is vulnerable to sense non-specific signals and the sample matrix effect. Overall, I-PCR tests indicate promising results based on Ag85B detection for an early diagnosis of TB. 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Several commercial antibody detection tests are available with imprecise, inconsistent and invariable results by ELISA, therefore, the WHO has recommended against the use of these tests [4] whereas direct detection of Mycobacterium tuberculosis antigens allow specific diagnosis of active TB independent of the host’s immune response [5]. Considering that antigen detection may be translated into a rapid POC TB diagnostic test, technology to improve their detection is urgently needed. Originally discovered by [6] immuno-PCR (I-PCR) combines the versatility and simplicity of ELISA with the enormous amplification capacity of PCR, which has been used for the ultralow detection of cytokines, protooncogenes and potential biomarkers for an early diagnosis of infectious and non-infectious diseases including TB infection [2] and that showed several-fold lower detection limit than analogous ELISA. We could detect up to 1femtogram (fg)/mL of mycobacterial recombinant purified protein such as early secreted antigenic target-6 (ESAT-6, Rv3875) and immunodominant antigen 85B (Ag85B, Rv1886c) and up to 10 fg/mL of cord factor (trehalos-6,6’dimycolate) by I-PCR, which was atleast 105-fold lower than ELISA [7,8]. We previously developed I-PCR based on streptavidin-biotin system for the detection of cocktail of regions of differences (RD) encoded proteins of M. tuberculosis such as ESAT-6, culture filtrate protein-10 (CFP-10, Rv3874), CFP-21 (Rv1984c) etc. [2]. Furthermore, by paired sample analysis, i.e., the detection of cocktail of RD proteins in sputum and detection of anti-RD antibodies in serum of the same PTB patients by I-PCR exhibited higher sensitivities (91% in smearpositive PTB cases and 72% in smear-negative PTB cases) and specificities (85%). 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引用次数: 2

摘要

结核病(TB)是一个严重的公共卫生问题,在全球传染病中与人类免疫缺陷病毒感染并列第一杀手。快速准确的诊断是控制疾病的关键,以便及早进行抗结核治疗。最近得到世界卫生组织(世卫组织)认可的GeneXpert MTB/RIF检测是结核病诊断领域的重大突破;然而,由于成本高,它在许多发展中国家的广泛实施受到限制。目前迫切需要设计一种快速、高灵敏度和可重复的就地治疗结核病诊断检测方法。针对IS6110、mpb64 (Rv1980c)、pstS1 (Rv0934)等的聚合酶链反应(Polymerase chain reaction, PCR)检测被广泛用于结核病患者的诊断[2],但PCR无法检测到结核病感染过程中大量循环的蛋白质、脂质、碳水化合物等非核酸分子。虽然酶联免疫吸附试验(ELISA)被广泛用于蛋白质检测,但当结核病患者体液中靶蛋白浓度较低时,它就失效了,而且还会导致体液的非特异性结合,最终导致特异性降低。有几种商用抗体检测方法可通过ELISA获得不精确、不一致和不变的结果,因此,世卫组织建议不要使用这些检测方法b[4],而直接检测结核分枝杆菌抗原可独立于宿主的免疫反应b[5]对活动性结核病进行特异性诊断。考虑到抗原检测可能转化为快速的POC结核诊断试验,迫切需要改进其检测的技术。最初是由[6]免疫PCR (I-PCR)发现的,它将ELISA的多功能性和简单性与PCR的巨大扩增能力相结合,已被用于细胞因子、原癌基因和潜在生物标志物的超低检测,用于包括结核感染[6]在内的传染性和非传染性疾病的早期诊断,其检测限比类似ELISA低几倍。我们可以通过I-PCR检测到高达1飞图(fg)/mL的分枝杆菌重组纯化蛋白,如早期分泌抗原靶蛋白-6 (ESAT-6, Rv3875)和免疫优势抗原85B (Ag85B, Rv1886c),以及高达10 fg/mL的脐带因子(海藻素-6,6 '二mycolate),这比ELISA至少低105倍[7,8]。我们先前建立了基于链亲和素-生物素系统的I-PCR,用于检测结核分枝杆菌的差异区(RD)编码蛋白如ESAT-6、培养滤液蛋白-10 (CFP-10, Rv3874)、CFP-21 (Rv1984c)等混合物[10]。此外,通过配对样本分析,即通过I-PCR检测痰中RD蛋白混合物和血清中抗RD抗体对同一肺结核患者的检测显示出更高的敏感性(痰检阳性肺结核病例91%,痰检阴性肺结核病例72%)和特异性(85%)。我们最近建立了基于琥珀酰亚胺基4-[n -马来酰亚胺甲基]-环己烷-羧酸酯(SMCC)的I-PCR检测PTB和肺外结核(EPTB)患者体液中Ag85B、ESAT-6、cord因子及其混合物。值得注意的是,I-PCR检测PTB患者痰液中Ag85B蛋白的灵敏度(PTB患者为80-83%,EPTB患者为66.6-68.6%)和特异性(PTB患者为90.3-92.8%,EPTB患者为90-92%)均优于Ag85B、ESAT-6和cord factor混合检测[7,8],后者也优于ELISA。基于SMCC的I-PCR执行速度更快,因为较少的孵育/洗涤步骤,并导致背景信号减少。结核病患者对不同结核分枝杆菌抗原的体液抗体反应是异质的。因此,采用I-PCR检测结核病患者血清中抗ag85b、抗esat -6和抗脐带因子抗体的鸡尾酒抗体,其灵敏度分别为84.1%和77.5%,特异性分别为90.9%和92%,优于ELISA和I-PCR检测单个抗体[9]。有趣的是,[10]使用17种结核分枝杆菌抗原进行ELISA检测抗体应答,对单个抗原检测抗体应答的敏感性为55.782.9%,特异性为62 ~ 92.2%,而对5种最佳抗原(Lipoarabinomannan、38 kDa、KatG、16 kDa、MPT63或Mtb39)检测抗体应答的敏感性为69.5%,特异性为91.1%。我们在对照中观察到基于抗原和抗体检测的I-PCR检测中只有少数假阳性结果,从而导致高特异性,这可能是由于在每个步骤中适当的清洗和使用适当的阻断溶液。少数假阳性结果的鉴定也表明I-PCR检测容易受到非特异性信号和样品基质效应的影响。 总体而言,基于Ag85B检测的I-PCR试验显示了早期诊断结核病的良好结果。我们需要设计一种具有成本效益的I-PCR检测方法,以便将其纳入常规诊断方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Immuno-PCR: Its Role in Serodiagnosis of Tuberculosis
Tuberculosis (TB) is a serious public health problem, which ranks equal with human immunodeficiency virus infection as the top most killer globally among the infectious diseases [1]. Rapid and accurate diagnosis is crucial to control the disease so as to initiate an early antitubercular therapy. The GeneXpert MTB/RIF assay recently endorsed by the world health organization (WHO) has been a major breakthrough in TB diagnostics; however, its wide implementation is restricted in many developing nations due to high cost. There is an urgent need to devise a rapid, highly sensitive and reproducible pointof-care TB diagnostic test. Polymerase chain reaction (PCR) tests targeting IS6110, mpb64 (Rv1980c), pstS1 (Rv0934), etc. are widely used for the diagnosis of TB patients [2] however PCR can’t detect non nucleic acid molecules such as proteins, lipids and carbohydrates, which are abundant in circulation during TB infection. Though enzyme-linked immunosorbent assay (ELISA) is widely used for the detection of proteins, but it fails when there is a low concentration of target proteins in body fluids of TB patients [3] and it also leads to nonspecific binding of body fluids that ultimately leads to reduced specificity. Several commercial antibody detection tests are available with imprecise, inconsistent and invariable results by ELISA, therefore, the WHO has recommended against the use of these tests [4] whereas direct detection of Mycobacterium tuberculosis antigens allow specific diagnosis of active TB independent of the host’s immune response [5]. Considering that antigen detection may be translated into a rapid POC TB diagnostic test, technology to improve their detection is urgently needed. Originally discovered by [6] immuno-PCR (I-PCR) combines the versatility and simplicity of ELISA with the enormous amplification capacity of PCR, which has been used for the ultralow detection of cytokines, protooncogenes and potential biomarkers for an early diagnosis of infectious and non-infectious diseases including TB infection [2] and that showed several-fold lower detection limit than analogous ELISA. We could detect up to 1femtogram (fg)/mL of mycobacterial recombinant purified protein such as early secreted antigenic target-6 (ESAT-6, Rv3875) and immunodominant antigen 85B (Ag85B, Rv1886c) and up to 10 fg/mL of cord factor (trehalos-6,6’dimycolate) by I-PCR, which was atleast 105-fold lower than ELISA [7,8]. We previously developed I-PCR based on streptavidin-biotin system for the detection of cocktail of regions of differences (RD) encoded proteins of M. tuberculosis such as ESAT-6, culture filtrate protein-10 (CFP-10, Rv3874), CFP-21 (Rv1984c) etc. [2]. Furthermore, by paired sample analysis, i.e., the detection of cocktail of RD proteins in sputum and detection of anti-RD antibodies in serum of the same PTB patients by I-PCR exhibited higher sensitivities (91% in smearpositive PTB cases and 72% in smear-negative PTB cases) and specificities (85%). We recently developed I-PCR based on succinimidyl 4-[N-maleimidomethyl]-cyclohexane-1carboxylate (SMCC) for the detection of Ag85B, ESAT-6, cord factor and the cocktail of these antigens in body fluids of PTB and extrapulmonary TB (EPTB) patients. Strikingly, detection of Ag85B protein in sputum samples of PTB patients by I-PCR exhibited better sensitivity (80-83% in PTB patients and 66.6-68.6% in EPTB patients) and specificity (90.3-92.8% in PTB patients and 90-92% in EPTB patients) than the detection of cocktail of Ag85B, ESAT-6 and cord factor [7,8] which was also superior to ELISA. I-PCR based on SMCC is quicker to perform due to less incubation/wash steps and lead to reduced background signals. The humoral antibody responses to different M. tuberculosis antigens in TB patients are heterogeneous. Therefore, the detection of cocktail of anti-Ag85B, anti-ESAT-6 and anti-cord factor antibodies in sera of TB patients was performed by I-PCR, which was superior (84.1% and 77.5% sensitivity and 90.9% and 92% specificity in PTB and EPTB patients, respectively) to ELISA as well as to the detection of individual antibodies by I-PCR [9]. Interestingly [10] used seventeen M. tuberculosis antigens for antibody response by ELISA, the sensitivity with individual antigens to detect the antibody response ranged from 55.782.9% with the specificity ranging from 62 to 92.2%, whereas the sensitivity reached 69.5% with a specificity of 91.1% with five optimal antigens (Lipoarabinomannan, 38 kDa, KatG, 16 kDa, MPT63 or Mtb39). We observed only few false positive results in controls with I-PCR assays based on both antigen and antibody detection thus leading to high specificity, which could be due to proper washing at each step and the use of appropriate blocking solutions. The identification of few false positive results also suggests that I-PCR assay is vulnerable to sense non-specific signals and the sample matrix effect. Overall, I-PCR tests indicate promising results based on Ag85B detection for an early diagnosis of TB. We need to devise a costeffective I-PCR test so that it can be included in the diagnostic panel for a routine use.
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