Simultaneous detection of ABO and Secretor-nonsecretor blood groups from forensic biological samples by fragment analysis

This paper describes the simultaneous detection of ABO and Secretor-nonsecretor (SE) blood groups from forensic biological samples by fragment analysis using the ABI PRISM^® 3130 genetic analyzer. The method allows the assay of well-known base changes at three nucleotide positions 261, 796 and 803 on cDNA of the ABO gene, and at 385 and 428 on cDNA of SE gene and a SE pseudo gene, so that reliable group prediction is established by the presence of representative alleles. As a result, simultaneous detection of ABO and SE blood groupings from biological samples was correctly determined by our methods.     

Detection of ABH blood group antigens in the saliva of Koreans and their stability according to storage of saliva samples

The purpose of the present study was to identify salivary molecules carrying the ABH blood group antigens in Koreans and to investigate the changes in these antigens according to processing and storage of saliva samples. Secretor or non-secretor phenotypes and salivary components carrying the ABH antigens were identified in 90 subjects, 30 subjects in each ABO blood group, by SDS-PAGE and immunoblotting. Saliva samples were then obtained from 12 secretors-two males and two females in each ABO blood group and aliquots of both fresh saliva samples and their supernatants after centrifugation were stored at room temperature, 4, -20 and -70 degrees C. The same experiments were performed after 1, 3 and 6 months to investigate changes in the blood group antigens. In all 68 secretors, high-molecular-weight salivary mucin (MG1) was found to be the primary carrier of the ABH antigens. A salivary component of approximately 80 kDa also carried H antigen in seven saliva samples of 22 blood type O secretors. The blood group antigens were better detected in centrifuged samples. In saliva samples preserved at room temperature and 4 degrees C, the blood group antigens were either not detected or detected as degraded molecules. No change was found in the blood group antigens in saliva samples preserved at -20 and -70 degrees C for 6 months.     

The rapid determination of the ABO group from body fluids (or stains) by dot enzyme-linked immunosorbent assay (dot-ELISA) using enzyme-labeled monoclonal antibodies

Using ABH enzyme-labeled monoclonal antibodies, the authors could rapidly detect the ABO group from body fluids and body fluid stains by the dot enzyme-linked immunosorbent assay (dot-ELISA). In this test, the antigen was immobilized on nitrocellulose paper; the entire piece of paper was coated with an appropriate dilution of enzyme-labeled McAb directly against the antigen of interest; and, finally, 3,3'-diaminobenzidine (DAB) substrate solution was added. The site of a positive reaction is clearly visible as a brown spot. We analyzed 521 samples and got satisfactory results. We also analyzed 99 practical case samples by this method and achieved the same results as those obtained by other researchers using other methods. This method is accurate, simple, direct, rapid, and sensitive; it also produces easily observed results, requires no equipment, and can be completed in 30 min. The test proved to be clearly more sensitive for the detection of the ABO blood group in secretor saliva than the conventional hemagglutination inhibition test. Also saliva diluted 10(-4) to 10(-5) and the ABO group of nonsecretor saliva and urine could be easily detected by this method.     

Determination of ABO(H) blood group substances from finger and toe nails

Thirty-six finger and toe nails were analyzed for ABO(H) blood group substances by the modified absorption elution method. The blood groups from nails were successfully determined in all the samples.     

Immunoenzyme AB0 blood group determination using a single hair. I

The immunoenzyme technique was used to determine the ABO blood group of strands of human scalp hair. The hair was obtained from 168 individuals of known blood groups (A1: n = 58; A2: n = 11; B: n = 28; O: n = 46; A1B: n = 16; A2B: n = 9). Immunostaining was carried out by using monoclonal anti-A, anti-B and anti-H as primary antibodies. Group-specific staining was clearly observed within the medulla of the hair. The ABO blood group of all hair samples was determined correctly by the Sternberger (PAP) or APAAP (immunoalkaline phosphatase) technique. The present study indicates that immunoenzyme techniques can be regarded as practical methods for determining ABO blood group of hair.     

A novel method for ABO genotyping using a DNA chip

ABO genotyping is often performed to identify the blood type of decomposed samples, which is difficult to be determined by a serological test. In this study, we developed a simple method for ABO genotyping using a DNA chip. In this method, polymerase chain reaction-amplified and fluorescent-labeled fragments in the ABO gene and primate-specific D17Z1 were hybridized with DNA probes on a chip designed to detect single nucleotide polymorphisms (SNPs) in the ABO gene and part of the D17Z1 sequence. Using blood samples from 42 volunteers and 10 animal species, we investigated whether the chip could be used to detect SNPs in the ABO gene and the D17Z1 sequence. This method was then applied to various forensic samples, and it was confirmed that this method was suitable for the simultaneous analyses of ABO genotyping and species identification. This method fulfills the recent need for the development of rapid and convenient methods for criminal investigations.     

Development and application of hydrogel oligonucleotide microchips for forensic-medical personal identification as illustrated by ABO locus

The article describes the method defining 5 alleles of ABO blood group typing system by molecular hybridization in hydrogel oligonucleotide microchip. The testing points were SNP variants in positions 261 and 297of exon 6 and in positions 646 and 657 of exon 7. Therefore, 5 ABO blood groups can be easily revealed: A, B, 0(1), 0(1v), 0(2). The method was tested on 10 DNA samples isolated from blood and saliva of unrelated individuals. The results were confirmed by sequencing of the identified allelic fragments. Estimation sensitivity was 25 pg of total DNA input. This technique is cost-effective and easy for use and, therefore, promising for forensic-medical personal identification.     

Immunoenzyme determination of ABO and secretor status in paraffin-embedded autopsy material

Using the indirect immunoperoxidase technique (PAP method), A, B, and H antigens were identified on formaldehyde-fixed, paraffin-embedded kidney tissue from 100 autopsies. Comparison with the serologic findings showed all our blood group determinations to be correct. The labeling of the collecting tubules was evaluated as characteristic of the secretor. The secretor status determined according to this parameter was unequivocally confirmed by the Lewis constellation in 78 of 82 cases; group Le(a-b-) could be differentiated with immunohistochemical methods in secretors and nonsecretors. Determination of ABO blood groups and secretion behavior with immunohistochemical methods was correct even in those cases where classic serology failed due to hemolysis and decomposition. Immunohistologic results obtained with monoclonal antibodies were better than those obtained with human sera.     

Effect of blood group active micro-organisms on the ABO grouping of human whole saliva

Three saliva samples with false positive ABO grouping results were assayed for blood group active organisms, using a variety of selective media to isolate representative strains from the salivary microflora. Eight out of 40, 8 out of 40 and 4 out of 30 strains from the three samples, respectively, showed blood group activity, which correlated well with the false positive specificities of the saliva samples. In all cases the false reaction only lasted a few days. Investigation of one of these samples before and after the appearance of the false positive activity yielded only one out of 40 blood group active organisms, using the same methods. Similar investigation of two "normal" saliva samples found none out of 40 and one out of 40 blood group active organisms, respectively. It is concluded that occasional false positive ABO grouping reactions of saliva samples are probably caused by the presence of unusually high numbers of blood group active micro-organisms, due to disturbances in the ecological balance of the salivary microflora.     

ABO genotyping by polymerase chain reaction.

ABO blood group system's genotyping by polymerase chain reaction in genomic DNA level is developed. The positions of nucleotide 258 and 700 of cDNA from A transferase were used to distinguish A, B, and O alleles by restriction enzyme digestion. To identify the 258th nucleotide, a 199- or 200-bp DNA fragment was amplified by PCR and digested with Kpn I. For the 700th nucleotide, a 128-bp PCR amplified fragment was designed and digested with Alu I. By examining the DNA fragment digested patterns, ABO genotypes were easily determined. Results obtained using this method on 20 ABO-known peripheral blood samples showed that this new technique could provide accurate ABO genotype. Biologic forensic samples, such as, blood stains, saliva stains, semen stains, hair, bone tissue, and semen contaminated with vaginal secretion were also successfully typed. This rapid, sensitive and reliable method should be applicable not only in forensic identification but also in medical examination.     

Evaluation of ABO and Lewis genotypes using primer extension preamplification

There are some difficulties with blood typing from ABO variant bloodstains and Lewis negative samples using serologic methods. In these samples, DNA analysis should be employed simultaneously to avoid errors in typing. Primer extension preamplification (PEP) produces copies of template DNA. The minimum quantity to examine nucleotide substitutions of ABO and Lewis genotypes by PCR ranged from 1 to 3 ng DNA. The PCR products with or without PEP treatment showed identical ABO and Lewis genotyping results. Performing both serologic and PCR testing served to crosscheck the ABO and Lewis grouping of such specimens. Errors in ABO and Lewis typing can be avoided as discrepancies are investigated further. The application of the PEP method to limited amounts of DNA samples for ABO and Lewis blood groupings is useful.     

One method of collecting fallen off epithelial cell

In this paper, the comparative analysis of ABO genotyping and serological typing was conducted in 360 unrelated blood samples from northern Chinese Han population using genotyping method and serological typing method, respectively. The results of ABO genotyping were obtained by Goldeneye 16BT STR plus ABO kit. The ABO serological types were determined by the antigen–antibody agglutination test. The ABO types were confirmed by the two methods and no contradiction types were found; two more types were obtained using the ABO genotyping method and the discrimination power was further improved; the information of ABO genotyping and 15 STRs could be obtained at the same time using the Goldeneye 16BT STR plus ABO kit.     

间接免疫酶组化法检测人指纹ABO血型

建立一套测定人指纹 ABO血型的方法体系。运用间接免疫酶技术和免疫印迹技术 ,对指纹胶纸提取的指纹、银粉显现提取的指纹、直接转移至硝酸纤维素膜 (NC膜 )上的指纹、银粉显现转移至 NC膜上的指纹、“5 0 2”胶熏显转移至 NC膜上的指纹等进行 ABO血型检测。上述 5种方法采集的 2 12枚指纹 ,绝大部分能正确地检出 ABO血型 ,检出率为 90 %～ 93.8% ;未能检出的样本为非分泌型人指纹。应用间接免疫酶技术及免疫印迹技术测定人指纹的 ABO血型的方法具有特异性强、准确可靠、检测方便等优点 ,在法庭科学中易推广应用 ,并能发挥重要的作用     

型特异性沉淀素血清检验人唾液斑精斑ABO血型的研究与应用

本文介绍了利用型特异性沉淀素血清环状沉淀法检验人唾液斑、精液斑ABO血型的方法与实验结果,并与中和试验及解离试验进行了比较。实验结果表明,本法操作简便,对多种干扰条件下的唾液斑、精斑均具有高度的型特异性,并能从分泌液与血液的混合斑中准确地鉴别出分泌液的血型。本法仅需0.4cm的分泌斑纱线即可进行血型鉴定,其灵敏度高于中和试验而略低于热解离试验,并能有效地检出陈旧分泌液斑中的型物质,因此适于在实际检案中应用。     

Lewis typing of human bloodstains by enzyme-linked immunosorbent assay (ELISA) using monoclonal anti-Le(a) and anti-Le(b)

The Lewis blood grouping of human dried bloodstains could be determined by an enzyme-linked immunosorbent assay (ELISA) using monoclonal anti-Le(a) and anti-Le(b) antibodies with an avidin-biotin complex (ABC). The bloodstains aged 1 year were used as samples, and approximately 1 mg of the stains was enough to type each Lewis antigen reliably by this method. The Lewis substances of 106 individual stains were correctly typed regardless of their ABO blood group system.     

人类精子ABO血型抗原的间接免疫荧光研究

应用间接免疫荧光技术,对40份精子标本进行 ABO 血型抗原检测。A 型人精子上存在 A 抗原;B 型人精子上存在 B 抗原;AB 型人精液中,一部分精子带有 A 抗原,另一部分精子带 B 抗原。各血型人的精子均有 H 抗原。精子血型抗原为本身所固有,并非来源于精浆。不同人的精子血型抗原含量各不相等,与其供体是否为分泌状态或强弱无直接关系。精子 ABO 血型抗原主要存在于精子的颈部和顶体等区域。     

Cytochemical detection of ABH antigens in human body fluids

The use of the peroxidase-anti-peroxidase (PAP) technique has been described previously for the detection of cellular antigens and in particular ABO antigens from tissue samples (Pedal and Hülle 1984; Pedal and Baedeker 1985; Pedal et al. 1985). In this survey, the PAP method has been employed to study the detection of ABO antigens in cells from body fluids of particular interest to forensic science, namely buccal cells and vaginal cells. Also tested, but in a limited number, were mixtures of body fluids and semen samples. No false reactions were obtained from buccal cells, all samples corresponding to the ABO blood type of the donor. Preliminary results from vaginal cells, vaginal/buccal cell mixtures, and semen were encouraging but must be treated with caution due to the limited number tested. Vaginal smears contaminated with semen showed varying degrees of nonspecificity.     

ABO genotyping by mutagenically separated polymerase chain reaction

ABO blood groups were determined by the mutagenically separated polymerase chain reaction (MS-PCR). The products from two sets of PCR reactions using the same program for the nucleotides at positions 261 and 703 from cDNA at the ABO locus were used to distinguish A, B and O alleles. Two forward mutagenic allele-specific primers of different lengths for the ABO polymorphic site were paired with the same reverse primer in each PCR reaction. The 216 bp fragment of the PCR products for the 261th nucleotide was A or B allele-specific and the 195 bp fragment was O allele-specific. The 126 bp fragment of the PCR products for the 703th nucleotide was B allele-specific and the 106 bp fragment was A or O allele-specific. The ABO genotypes were determined by the intersection of the predicted alleles from these two PCR reactions. The PCR products were obtained using 10 ng of DNA in 50 μL of PCR reaction mixture, and electrophoresed in 4% agarose gel. In this study, 265 ABO-phenotype known samples (A: 31, B: 48, AB: 6 and O: 180) in Chinese were used. The results of ABO genotypes were AA: 1, AO: 30, BB: 2, BO: 46, AB: 6 and OO: 180. These results were confirmed by the PCR-RFLP ABO genotyping method. This technique is a simple, rapid, and reliable method for ABO genotyping.     

Determination of ABO blood grouping from human oral squamous epithelium by the highly sensitive immunohistochemical staining method EnVision+

Using the highly sensitive immunohistochemical staining method EnVision+, which employs a dextran polymer reagent for the secondary antibody, the detection of the ABH antigens was attempted in the oral squamous epithelium. This new technique uses monoclonal antibody as a primary antibody and it takes about three hours for staining. The time is much shorter than conventional absorption-elution testing or absorption-inhibition testing for the determination of ABO blood grouping. Secretor saliva samples were stained at strong intensity by the antibody, which corresponded to its blood group and anti-H. On the one hand, nonsecretor saliva samples were stained at strong intensity only by the antibody that corresponded to its blood group, and at weak intensity only by anti-H. Since human oral squamous epithelium antigens were stained specifically by this method, we can examine the ABO blood group of saliva samples and perform cytodiagnosis at the same time. Our research suggested that the EnVision+ Method is a useful technique for ABO blood grouping of saliva in forensic cases.     

ABO基因分型及其在法医学中的应用

为建立一种ABO血型系统基因分型方法，采用PCR-RFLP技术，成功地将ABO系统区分为AA，AO，AB，OO，BB，BO六种基因型。对240名中国汉族无关个体血样的ABO（基因型频率调查结果表明，6种基因型的频率分布为0．0125～0．3834，符合Hardy－Weinbeng遗传平衡法则（P＞0．1），其DP值为0．8161。家系分析表明，亲代a、b、o基因传递遵守孟德尔遗传规律。对法医学中常见的血痕、混合斑、骨组织及毛发根部等生物样品进行检测，均能准确判定ABO基因型，并可在实际案件鉴定中应用。