Lublin D M, Mallinson G, Poole J, Reid M E, Thompson E S, Ferdman B R, Telen M J, Anstee D J, Tanner M J
Department of Pathology, Washington University School of Medicine, St Louis, MO 63110.
Blood. 1994 Aug 15;84(4):1276-82.
The human erythrocyte blood group system Cromer consists of high-incidence and low-incidence antigens that reside on decay-accelerating factor (DAF; CD55), a glycosyl-phosphatidylinositol-anchored membrane protein that regulates complement activation on cell surfaces. In the Cromer phenotypes Dr(a-) and Inab there is reduced or absent expression of DAF, respectively. This study investigated the molecular basis of the reduced DAF expression by polymerase chain reaction amplification of genomic DNA and RNA/cDNA obtained from Epstein-Barr virus-transformed lymphoblastoid cell lines. Sequence analysis of the Inab propositus showed a single nucleotide substitution in exon 2 of the DAF gene and at the corresponding position in the cDNA, G314-->A resulting in Trp53-->Stop. This truncation near the amino terminus explains the complete absence of surface DAF in the Inab phenotype. A similar analysis was performed for two Dr(a-) individuals, including KZ, who was previously reported to be Inab phenotype but is now shown by immunochemical and serologic methods to be Dr(a-) phenotype. A single nucleotide change was found in exon 5 of the DAF gene, C649-->T resulting in Ser165-->Leu, which we had previously shown to lead to loss of the Dra epitope. However, two species of cDNA were found, one encoding full-length DAF with the single amino acid change and the more abundant species having a 44-nucleotide deletion. The 44 nucleotide deletion includes the single polymorphic site, which creates a cryptic branch point in the Dr(a-) allele that leads to use of a downstream cryptic acceptor splice site. This shifts the reading frame and leads to a premature stop codon that precludes membrane anchoring. Thus, the single point mutation in the Dr(a-) phenotype results in a novel use of alternative splicing and provides a molecular explanation for both the antigenicity and the reduced DAF expression seen in this phenotype.
人类红细胞克罗马血型系统由高频率和低频率抗原组成,这些抗原位于衰变加速因子(DAF;CD55)上,DAF是一种糖基磷脂酰肌醇锚定的膜蛋白,可调节细胞表面的补体激活。在克罗马血型表型Dr(a-)和Inab中,DAF的表达分别减少或缺失。本研究通过对从爱泼斯坦-巴尔病毒转化的淋巴母细胞系获得的基因组DNA以及RNA/cDNA进行聚合酶链反应扩增,来探究DAF表达减少的分子基础。对Inab先证者的序列分析显示,DAF基因外显子2以及cDNA的相应位置存在单核苷酸替换,G314→A,导致Trp53→终止密码子。氨基末端附近的这种截短解释了Inab表型中表面DAF完全缺失的原因。对两名Dr(a-)个体进行了类似分析,其中包括KZ,KZ之前被报道为Inab表型,但现在通过免疫化学和血清学方法显示为Dr(a-)表型。在DAF基因外显子5中发现了一个单核苷酸变化,C649→T,导致Ser165→Leu,我们之前已证明这会导致Dra抗原决定簇丢失。然而,发现了两种cDNA,一种编码具有单个氨基酸变化的全长DAF,另一种更丰富的cDNA有44个核苷酸的缺失。44个核苷酸的缺失包括单个多态性位点,这在Dr(a-)等位基因中产生了一个隐蔽的分支点,导致使用下游的隐蔽剪接受体位点。这会改变阅读框并导致提前出现终止密码子,从而阻止膜锚定。因此,Dr(a-)表型中的单点突变导致了可变剪接的新用法,并为该表型中观察到的抗原性和DAF表达减少提供了分子解释。
