A cloned unique gene of drosophila melanogaster contains a repetitive 3′ exon whose sequence is present at the 3′ ends of many different mRNAs

We have started to study a cloned genomic DNA fragment ～7 kb long (denoted as H55) from the 7B3-4 region in the X chromosome of Drosophila melanogaster. The major part of the fragment is a single-copy sequence. It directs the synthesis of mRNA that makes up ～0.1% of the cytoplasmic poly(A)⁺ RNA from Drosophila embryos. The H55 gene is split by an intervening sequence, yielding a large single-copy exon and a small repetitive 3′ exon represented by hundreds of copies in the genome. This repetitive sequence (“suffix”) is also present at the 3′ ends of ～2% of all cytoplasmic poly(A)⁺ RNA chains.     

Abnormally spliced messenger RNA in erythroid cells from patients with β+ thalassemia and monkey cells expressing a cloned β+-thalassemic gene

The reduced β-globin synthesis characterizing the β⁺ thalassemia phenotype has been shown to be caused by anomalous processing within the small Intervening sequence (IVS1) of the β-globin mRNA precursor. The β-globin gene from such patients contains a single base substitution within IVS1, located 22 bp from the 3′ junction between IVS1 and exon 2, creating an alternative splice site within IVS1 and resulting in retention of the 3′-terminal 19 bases of IVS1. We have identified this abnormally spliced mRNA in the reticulocyte RNA of two patients with β⁺ thalassemia, by S1 nuclease mapping and primer-extension analysis. Moreover, a cloned β⁺-thalassemic gene preferentially generated the anomalously spliced RNA when expressed In monkey kidney cells. The anomalously spliced RNA constituted approximately 80%–90%, and normal β RNA approximately 10%–20%, of the total β mRNA. In contrast, the small amount of β mRNA present in reticulocytes from such patients consisted predominantly of normal β mRNA. These results suggest that the reduced amount of normally functioning β mRNA present in such patients results from preferential processing at the alternative splice site, with subsequent Instability, reduced nuclear processing and/or inadequate cytoplasmic transport of the abnormal RNA species.     

Isolation and sequence analysis of a hybrid delta-globin pseudogene from the brown lemur

The β-globin gene cluster of the brown lemur, a prosimian, is very short and contains a single ?-, γ- and β-globin gene, with an additional β-related gene sequence between the γ- and β-globin genes. Brown lemur DNA was cloned into the bacteriophage vector λL47.1 and a recombinant was isolated which contained an 11 × 10³ base insert including the β-globin gene and the additional putative β-globin pseudogene. The nucleotide sequence of this β-related gene was completely determined. A complete gene sequence was found, containing four frameshift mutations sufficient to establish its pseudogene status. The gene was interrupted by two intervening sequences with sizes and locations typical of mammalian β-related globin genes. The pseudogene sequence was compared in detail with human ?-, γ-, δ- and β-globin genes. The beginning of the pseudogene, from the 5′ flanking region to the second exon, was homologous to the corresponding regions of the human ?- and γ-globin genes. In contrast, the second intron, third exon and 3′ flanking region showed a remarkably close homology to the δ-globin, but not β-globin, gene of man. This suggests that the δ-globin gene is not the product of a recent gene duplication, but instead is present in most or all primates. This gene has been silenced on at least two separate occasions in primate evolution (in lemurs and in old world monkeys). In addition, the 5′ end of the lemur ψδ gene appears to have exchanged sequences with an ?- or γ-globin gene, and an analogous exchange with the β-globin gene seems to have occurred recently in the human δ-globin gene. The evolution and function of the δ-globin gene are discussed.     

Secondary structure of mouse and rabbit α- and β-globin mRNAs: Differential accessibility of α and β initiator AUG codons towards nucleases

The nucleotide sequence from the 5′ terminus inward of one third of mouse α- and β^maj-globin messenger RNAs has been established. In addition, using 5′ ³²P end-labeled mRNAs as substrates and S1 and T1 nucleases as probes for single-stranded regions, the secondary structures of mouse and rabbit α- and β-globin mRNAs have been analyzed. Our results indicate that the AUG initiator codon in both mouse and rabbit β-globin mRNA is quite susceptible to cleavage with S1 and T1 nucleases, suggesting that it resides in a single-stranded exposed region. In contrast, the initiator AUG in the α-globin mRNA of both species is inaccessible to cleavage, indicating that it is either buried by tertiary structure or is base-paired. Since the rate of initiation of protein synthesis with β-globin mRNA in rabbit reticulocyte is 30–40% faster than for α-globin mRNA, these results imply a possible correlation between the differential rates of initiation with these two mRNAs and the accessibility of the respective AUG initiator codons.     

Restriction endonuclease analysis of human globin genes in cellular DNA

Using samples of human cellular DNA digested with restriction endonucleases Eco RI, Hind III, Hinc II, Bam HI, Alu I, or Hae III, we were able to localize globin gene fragments separated by agarose gel electrophoresis. The fragments were transferred to nitro-cellulose filters and identified by hybridization to [³²P] cDNA for total adult globin mRNA. The α-globin gene fragments were specifically identified by their presence in normal controls and absence in DNA from homozygous α-thalassemia, a genetic disorder due to deletion of α-globin genes. In addition, the patterns with Hind III indicate a 4.1 kb distance between the centers of the normal duplicated α-globin gene loci.     

Absence of messenger RNA and gene DNA for β-globin chains in hereditary persistence of fetal hemoglobin

The relative amounts of α- and β-globin mRNA and globin gene DNA were measured in reticulocyte RNA and lymphocyte DNA of an individual with homozygous hereditary persistence of fetal hemoglobin whose red blood cells contain 100% fetal hemoglobin (Hb F: α₂γ₂). Molecular hybridization assays used as probes full-length DNA copies of human α- and β-globin messenger RNA. The results of these hybridization assays demonstrated the expected amounts of α-globin mRNA and gene DNA, but absence of β-globin mRNA and absence of β-globin gene DNA. In the individual studied, hereditary persistence of fetal hemoglobin is associated with total deletion of the β-globin structural gene.     

用富集文库克隆人胰岛素基因组基因

通过构建可富集人胰岛素基因的λ噬菌体文库,克隆了人胰岛素基因组基因．首先从中国人血液白细胞中提取到人基因组ＤＮＡ,用ＥｃｏＲⅠ和ＢｇｌⅡ对基因组ＤＮＡ进行全酶切,经０．４％琼脂糖凝胶电泳,特异回收９．５ｋｂ左右的ＤＮＡ片段．将该片段与λＥＭＢＬ３／ＢａｍＨⅠ臂连接,构建成一个特殊的人基因组λ噬菌体文库（富集文库）,效价为２×１０４．同时采用ＰＣＲ方法及用引物Ⅰ：５′ＧＧＡＣＡＧＧＣＴＡＣＡＴＣＡＧＧＡＡＧＡＧＧ３′,引物Ⅱ：５′ＣＴＧＣＧＴＣＴＡＡＴＴＧＣＡＧＴＡＧＴＴＣ３′,从人基因组ＤＮＡ中扩增出一段含胰岛素基因的１．３６ｋｂＤＮＡ片段,做为放射性标记探针,对文库进行了噬菌斑原位杂交筛选,从１×１０４个噬菌斑中筛选到一个含人胰岛素基因组基因的阳性克隆,并进一步完成了亚克隆和该基因１７３２ｂｐＤＮＡ序列的测定．结果该基因的１７３２ｂｐＤＮＡ序列包括部分５′端和３′端与国外发表的人胰岛素α型等位基因的序列相同     

Organization of human δ- and β-globin genes in cellular DNA and the presence of intragenic inserts

We have analyzed human cellular DNA for its δ- and β-globin gene sequence content by separation of restriction enzyme fragments by agarose gel electrophoresis; transfer of the DNA fragments to nitrocellulose filters; hybridization of filters with ³²P-β-globin cDNA; and analysis by autoradiography. A short cDNA has been used to identify specifically the 3′ end of the genes and to orient the fragments. A comparison of the globin gene fragments generated by normal and Lepore DNA has been used to distinguish fragments representing DNA sequences between the δ and β genes and those containing sequences flanking either 5′ to the δ gene or 3′ to the β gene. The results indicate that unique restriction fragments are presented in normal DNA and absent in Lepore DNA, and allow preliminary ordering of these fragments on a restriction enzyme map. In addition, the Lepore, δ- and β-globin genes have been found to contain at least one inserted nucleotide sequence of about 1000 bases which is not represented in mature globin mRNA.