成都地区汉族Gc亚型的分布及血痕中Gc亚型的检测

作者用免疫固定薄层聚丙烯酰胺凝胶等电聚焦(PAGIF)技术,调查了成都地区无关的125名健康汉族人血清Gc亚型分布。其6种亚型频率(%)分别为:Ge1F=20.8,Ge1S=8.0,Gc1F-1S=18.4,Gc2-1F=30.4,Gc2-1S=16.0和Gc2=6.4。Gc的基因频率为:Cc~(1F)=0.452,Gc~(1S)=0.252和Gc~2=0.296。对保存于室温条件下20周的陈旧血痕进行了Gc亚型定型,获得满意结果。     

改良磺基水杨酸法显示GC谱带及两个新的GC变异型的发现

本文采用改良了Kühnl报告的磺基水杨酸沉淀法显示GC谱带的技术,显示了六种常见的GC亚型和GC变异型。并且采用该法发现了两个新的GC变异型基因Gc~(1c3)和Gc~(2c7),其基因频率分別为0.0008和0.0004。本法经济、快速,谱带清晰,可取代需抗GC血清的常规免疫固定技术。     

A method for subtyping group-specific component in bloodstains

A method is described for subtyping group-specific component (Gc) derived from human bloodstains. Bloodstained cuttings were extracted in 6 M urea. The extracts were subjected to ultrathin-layer polyacrylamide gel isoelectric focusing in the pH 4.5-5.4 range. After isoelectric focusing, Gc was detected by immunofixation in cellulose acetate membranes. This method permitted the successful typing of Gc in at least four-month-old bloodstains maintained at room temperature. Bloodstains from 266 liquid blood samples of known origin were subjected to both this method and immunofixation conventional agarose gel electrophoresis with no phenotypic discrepancies observed. The Gc population data for Whites from Baltimore, Maryland, were homogeneous with white sample populations from other geographical locations within the U.S.A.; while Gc data from northern U.S.A. black sample populations appeared to be heterogeneous compared with a southern United States black sample population.     

The typing of group-specific component (Gc protein) in human blood stains

It is known that the typing of group-specific component (Gc protein) in human blood stains is difficult since Gc protein of the extracts of blood stains migrates more anodally to the α₁-globulin region in agar-gel immunoelectrophoresis, while Gc protein in liquid blood normally migrates to the α₂-globulin region. We have reported that the Gc protein found in the α₁-region is the result of binding of actin to Gc protein (Shinomiya, K., Kimura, H., Yoshida, K., and Shinomiya, T., J. Biochem., 92 (1982) 1163–1171, which renders it difficult to determine the Gc-phenotypes in the blood stains. On the basis of the above findings, we developed the method of phenotyping the Gc protein of human blood stains by agar-gel immunoelectrophoresis. Since the binding activity of actin to Gc protein is lost after treatment with a high concentration of guanidine HCl, the extracts of blood stains were treated with 4 M guanidine HCl to dissociate Gc protein and actin and then dialyzed to remove guanidine HCl. By this method we are able to determine the phenotypes of Gc protein in blood stains. The method we have developed is a useful tool in the forensic laboratory.     

A stability study on Gc subtyping in bloodstains: comparison by two different techniques

The limits of determination of Gc subtypes in bloodstains were compared between the immunofixation method and the sulfosalicylic acid precipitation method using isoelectric focusing on polyacrylamide gel. By the immunofixation method Gc subtyping in bloodstains was successfully made at 37 degrees C after 7 weeks, at room temperature after 17 weeks and at 4 degrees C even after 25 weeks storage. By the sulfosalicylic method Gc subtypes were no longer able to be determined a few weeks after stain formation. The superiority of the results obtained by the immunofixation method makes it the recommended method for the Gc subtyping from bloodstains in medicolegal practice.     

Group specific component: isoelectric focusing subtyping and immunoblot detection

A method for the detection of group specific component (Gc) by immunoblotting, following isoelectric focusing (IEF), is described. This isoelectric focusing method resolves the six common phenotypes of Gc using a narrow range pH 4.5 to 5.4 ampholyte. The Gc proteins were passively transferred from the IEF gel to nitrocellulose and detected with goat anti-Gc followed by peroxidase labeled anti-goat immunoglobulin (Ig) antibody. The increased sensitivity of this technique results in the typing of stains older than one year and also those stains with minimal concentrations of the Gc protein. The polyacrylamide gel can also be used for the subtyping of esterase D.     

A comparison of the sensitivity of typing group-specific component (Gc) and the phosphoglucomutase (PGM1) locus in control and casework bloodstains by three isoelectric focusing methods

The performance of typing group-specific component (Gc) in bloodstains by two isoelectric focusing methods followed by its detection with silver staining has been compared with an established forensic system of typing phosphoglucomutase (PGM1) locus phenotypes by isoelectric focusing (IEF) in 1 mm gels. For Gc typing ultra-thin isoelectric focusing (UTIEF) gels and immobilized pH gradient (IPG) gels were used. Both laboratory prepared stains and casework stains were examined. The Gc UTIEF method is approximately eight times more sensitive than the existing PGM1 1 mm IEF method for control and casework stains. However, on average, a larger amount of stain was taken from casework stains than control stains for each typing system. A total of 53 casework stains were examined. Comparable success rates of 62% and 64% were obtained for typing Gc on UTIEF gels and PGM1 by 1 mm IEF, respectively. A success rate of 55% was obtained for typing Gc on IPGs. Bloodstains that were over 200 days old were successfully grouped by all three methods.     

Gc亚型检测的复合MS-PCR法及其应用

目的探讨建立Gc亚型检测的复合MS-PCR法及其应用价值。方法根据Gc基因中的2处点突变,设计2对片段相差5bp的等位基因特异性引物和1条公共引物进行复合MS-PCR,分析Gc多态性,并调查武汉地区218例汉族无关个体Gc多态性和鉴定10例亲子关系。结果复合MS-PCR检测的Gc基因型,与AmpliTypePM试剂盒的分型结果一致;武汉地区汉族人群Gc基因的3个常见等位基因Gc1F、Gc1S、Gc2的基因频率分别为0.4816、0.2592、0.2592,观察杂合度(Hobs)、期望杂合度(Hexp)、多态性信息含量(PIC)、个人识别能力(DP)、非父排除率(PE)分别为0.6193、0.6359、0.6253、0.7974、0.3480,基因型分布符合Hardy-Weinberg平衡;真三联体和非真三联体亲子鉴定各5例,前者不排除父子关系,与常规STR分型一致,后者经Gc-MS-PCR分型排除2例。结论建立复合MS-PCR法检测Gc亚型在法医物证鉴定中有实用价值。     

The detection of group-specific component from urine samples

The detection of group-specific component (Gc) from serum and bloodstains has been widely used in the forensic laboratory. A recent increase in substituted or adulterated urine samples in various drug screening programs has necessitated methods to determine the donor. This paper discusses the detection of Gc from urine samples. The samples were concentrated and applied to ultrathin polyacrylamide gel and focused for 150 min. This method separates the samples into the three common phenotypes found in all human populations. A nitrocellulose membrane blotting technique was used to detect the Gc bands. Serum and urine samples were collected from each individual and were typed for Gc. Urine samples tested after 6 months of storage (4 degrees C) were still readable. This method provides the forensic laboratory with an additional test from a body fluid which, until recently, provided little information.     

Detectability of group-specific component (Gc) in aged bloodstains

An improved method of group-specific component (Gc) typing was conducted electrophoretically on agarose gel. Individual bloodstains randomly collected from different individual donors over a five-year period at intervals of approximately one month were checked for Gc activity. Group-specific component was typed accurately in dried bloodstains stored at room temperature up to 43 months in age. From 100 different donors, bloodstains ranging in age from 38 to 43 months were tested by the methods described and 73% of the samples were interpretable for Gc.     

Group specific component subtyping in bloodstains by separator isoelectric focusing in micro-ultrathin polyacrylamide gels followed by immunoblotting

The identification of group specific component (Gc) subtypes derived from blood-stains by separator isoelectric focusing in micro-ultrathin polyacrylamide gels (interelectrode distance: 50 mm) containing 4.5 to 5.4 pharmalytes is described. The separation achieved between Gc 1F and Gc 1S bands is compared favorably with that obtained using separator isoelectric focusing in conventional polyacrylamide gels dimensions (interelectrode distance: 110 to 120 mm). The technique is rapid and economical, and the immunoblotting method described is more sensitive than immunofixation followed by silver staining.     

Rapid phenotyping of the group specific component by immunofixation on cellulose acetate

Determination of the genetically controlled variants of the polymorphic Gc system was achieved by electrophoresis on cellulose acetate membranes followed by immunofixation with a specific anti-Gc antiserum. The method is applicable to plasma, whole hemolyzed blood, and dried blood. Multiple specimens can be analyzed simultaneously within 60 to 80 min. The cellulose acetate electrophoretogram of the Gc variants remains as a permanent record.     

应用窄范围两性电解质聚丙烯酰胺凝胶等电聚焦法检验人血痕中的Gc亚型

采用窄范围两性电解质聚丙烯酰胺凝胶等电聚焦加免疫吸印技术,对人血痕中 Gc 亚型进行分型,并调查了北京地区284名无关汉族群体的 Gc 亚型的分布及基因频率。结果显示:Gc~(IF)0.4287,Gc~(IS)0.2500.Gc~20.3222.观察值与期望值吻合度良好(ΣX~2=0.7530,P>0.80).Gc 的个人识别率为0.6507.且室温下保存7周的血痕可以准确判型。将调查结果与中国其它地区及国外不同人种 Gc 亚型的表型的分布与基因频率进行了比较,发现地理及人种间差异明显。     

The identification of a victim using the DGGE method for trace deposits collected on adhesive film

The denaturant gradient gel electrophoresis (DGGE) method was used in order to simultaneously estimate the genotypes of different factors in a gel plate consisting of one sheet. A genotype analysis of the blood groups (MN, Duffy, Kidd type) and serotype (Gc system) was carried out. DNA samples were extracted from trace deposits which were transferred on adhesive film from a blood trace obtained from a car tire after a fatal car accident. The reference DNA was prepared from the victim's blood. The PCR amplification fragments were amplified from the gene which controlled each blood group. The primers were designed in order to analyze the genotypes with one to three base substitutions in the amplification product. The denaturant concentration limit of the gel for the DGGE method to detect each genotype of the blood groups (MN, Duffy, Kidd type and Gc system) and other conditions of electrophoresis were performed according to previously methods.The each genotype of the blood groups and the Gc system were all simultaneously distinguished in one plate.     

The phenotypic frequencies of group specific component and alpha-2-HS-glycoprotein in three ethnic groups. The use of these proteins as racial markers in forensic biology

The phenotypic frequencies of group-specific component (Gc) and alpha-2-HS-glycoprotein (A2HS) were determined in White European, Asian and Afro-Caribbean populations. Typical allele frequencies were observed for Gc, with Gc 1S being the major allele for the first two groups and Gc 1F being the major allele for Afro-Caribbeans. For all groups the dominant A2HS allele was A2HS 1, although Asians had a significantly higher proportion of this allele than the White Europeans. Gc and A2HS either singly or in combination with other blood grouping systems provide good discriminating potential. The A2HS 10 allele was detected with a very low frequency in the White European group (A2HS 10 = 0.0013) and was not detected in the Asian group, while the Afro-Caribbean group had a relatively high frequency of this allele (A2HS 10 = 0.0966). The different distribution of the Gc 1F and A2HS 10 alleles in White Europeans and Asians compared with Afro-Caribbeans, can be used to determine the likelihood of blood coming from an Afro-Caribbean.     

Group-specific component: a review of the isoelectric focusing methods and auxiliary methods available for the separation of its phenotypes

This review compares the major isoelectric focusing methods that have been published for the separation of group-specific component (Gc) phenotypes since 1978. The various parameters of gel composition, size, electrical and running conditions and sample application points are listed. More current auxiliary methods are also listed. These relate to the extraction of Gc from bloodstains and its identification after isoelectric focusing. Protocols are then recommended for the forensic analysis of Gc phenotypes.     

Vitamin D binding protein (Gc) subtypes by isoelectric focusing and immunoblotting

The polymorphism of the human vitamin D binding protein (Gc system) was investigated in a total of 149 sera from unrelated healthy Egyptians residing in Tanta City, Gharbiya Governorate, Nile Delta of Egypt, using isoelectric focusing (IEF) in thin-layer polyacrylamide gel followed by immunoblotting. The estimated gene frequencies were Gc1s = 0.540, Gc1f = 0.242 and Gc2 = 0.218.     

Gc subtypes determined by ultrathin-layer isoelectric focusing. Distribution in the Veneto population (Italy)

The distribution of Gc phenotypes in the population of Veneto was investigated by ultrathin-layer isoelectric focusing. In our sample (n = 732) the six common phenotypes, Gc 1S, 1F, 1S1F, 2, 2-1S, 2-1F and a further phenotype, GC 1S1C3, were observed and the following frequencies calculated: Gc 1S = 0.560792; GC 1F = 0.159153; Gc2 = 0.277323; Gc 1C3 = 0.002732. Our gene frequencies have been compared with those found in other populations.     

Simultaneous typing of C3 and Tf and of Gc and Bf on Cellogel electrophoresis

A method is described to type C3 and Tf on the same Cellogel strip (and Bf simultaneously on a parallel strip). A different method allows to type Gc and Bf on one Cellogel strip. These methods are rapid, easy and reliable, although agarose electrophoresis is a little more effective.     

Gel electrophoresis of the alpha-2-Gc globulin group under various conditions

Our experiments confirm the transformation of the group-specific component Gc into alpha 1-globulin. This transformation was more marked in blood samples subjected to repeated freezing-thawing procedures, and was very weak in samples subjected to repeated freezing-thawing procedures after mixing serum and red blood cells. The active factor responsible for this transformation was inhibited by heating at 56 degrees C for one minute in a water-bath. The transformation of the group-specific component was accomplished immediately by mixing serum and extract of platelets. The extract of platelets induced an increase in the rate of migration of all Gc components on immunoelectrophoresis, and it induced a decrease in the isoelectric point of all Gc components on Ampholine PAG plates with a pH range of 4 to 6.5. It induced a decrease in the rate of migration of all Gc components on polyacrylamide gel (7.5%) electrophoresis. A similar transformation was induced by homogenized fluid of cardiac muscle of cow and chicken, and pectoral muscle of the chicken.