Molecular consequences of two formaldehyde-induced mutations in the alcohol dehydrogenase gene ofDrosophila melanogaster

Adhfn23 and Adhfn24 are two formaldehyde-induced, homozygous-viable, alcohol dehydrogenase-null mutants that bear lesions in the gene that codes for the alcohol dehydrogenase (ADH; EC 1.1.1.1) of Drosophila melanogaster. Adhfn23 contains a 34-base pair deletion in the C-terminal coding region of the alcohol dehydrogenase structural gene. By immunological and molecular analysis, we show that the deletion shifts the translation reading frame and results in a prematurely truncated polypeptide product (10 amino acids shorter than wild type) that cross-reacts with antibody raised against ADH. The steady-state level of alcohol dehydrogenase mRNA present in this mutant is close (97%) to that in the wild type, but the steady-state level of alcohol dehydrogenase-like protein is 50% lower. Moreover, the rate of alcohol dehydrogenase synthesis in Adhfn23 flies is reduced to 60% of that found in the wild type. Hence both the rate of synthesis and the rate of degradation of alcohol dehydrogenase are affected. In contrast, Adhfn24 which contains an 11-base pair deletion in the N-terminal coding region of the ADH gene, synthesizes no immunodetectable protein, and the amount of alcohol dehydrogenase mRNA is less than half that of wild-type flies. As with Adhfn23, the deletion in Adhfn24 results in a change in the reading frame. Unlike Adhfn23, however, nucleic acid sequence data indicate that polypeptide chain elongation can proceed for a considerable distance (over 130 amino acids) beyond the deletion. Based upon antigenic binding-site predictions, the resultant aberrant protein (projected 195 amino acids in length) would share few antigenic sites with the alcohol dehydrogenase from the wild type, which may account for the lack of immunoprecipitable material in this mutant. The contrasting effects these two deletions have on the Drosophila ADH mRNA levels and ADH protein levels are discussed.     

Four novel PEPD alleles causing prolidase deficiency.

Mutations at the PEPD locus cause prolidase deficiency (McKusick 170100), a rare autosomal recessive disorder characterized by iminodipeptiduria, skin ulcers, mental retardation, and recurrent infections. Four PEPD mutations from five severely affected individuals were characterized by analysis of reverse-transcribed, PCR-amplified (RT-PCR) cDNA. We used SSCP analysis on four overlapping cDNA fragments covering the entire coding region of the PEPD gene and detected abnormal SSCP bands for the fragment spanning all or part of exons 13-15 in three of the probands. Direct sequencing of the mutant cDNAs showed a G-->A, 1342 substitution (G448R) in two patients and a 3-bp deletion (delta E452 or delta E453) in another. In the other two probands the amplified products were of reduced size. Direct sequencing of these mutant cDNAs revealed a deletion of exon 5 in one patient and of exon 7 in the other. Intronic sequences flanking exons 5 and 7 were identified using inverse PCR followed by direct sequencing. Conventional PCR and direct sequencing then established the intron-exon borders of the mutant genomic DNA revealing two splice acceptor mutations: a G-->C substitution at position -1 of intron 4 and an A-->G substitution at position -2 of intron 6. Our results indicate that the severe form of prolidase deficiency is caused by multiple PEPD alleles. In this report we attempt to begin the process of describing these alleles and cataloging their phenotypic expression.     

Molecular relationships between alcohol dehydrogenase null-activity alleles from natural populations of Drosophila melanogaster.

Alcohol dehydrogenase null-activity alleles extracted from a number of natural populations of Drosophila melanogaster in Tasmania were shown to be molecularly similar by probing, with an oligonucleotide specific to an inserted region in intron 2 of the gene, genomic DNA amplified by the polymerase chain reaction. This insertion had previously been shown to be the cause of the loss of activity in one of the null alleles whose DNA sequence was known. Three Adh null alleles from mainland populations did not contain the insertion. Two of these null alleles, extracted from the Coffs Harbour population in different years, were cloned, and their DNA sequences showed that they were identical and that both had a 438-bp deletion which removed most of exon 2. The third null allele, identified in a sample of flies from Chateau Tahbilk, was shown by 4-bp restriction-endonuclease mapping to contain a 320-bp insertion in intron 1, although this may not be the cause of the loss of activity. The data show that at least three different Adh null alleles have been found in Australian populations and that at least two have been maintained as heterozygotes over a period of years.     

The Finnish type of the LDL receptor gene mutation: molecular characterization of the deleted gene and the corresponding mRNA

In one third of Finnish patients with the heterozygous form of familial hypercholesterolemia the disease is due to a gross deletion at the 3'-end of the LDL receptor gene. The present study demonstrates that an 8-kb deletion completely eliminates exons 16 and 17 and a part of exon 18. Cloning and partial sequencing of a DNA fragment from the mutated allele indicated that the 5'-boundary of the deletion lies within intron 15 while the 3'-breakpoint is located at nucleotide 3390 in exon 18. RNA blot hybridization studies revealed that the mutated allele encodes a truncated 4.2 kb mRNA (normal, 5.3 kb). This type of mutation has not been reported in other ethnic groups.     

Deletion within the CYP17 gene together with insertion of foreign DNA is the cause of combined complete 17 alpha-hydroxylase/17,20-lyase deficiency in an Italian patient.

The molecular basis of 17 alpha-hydroxylase/17,20-lyase deficiency syndrome in a 14-yr-old 46,XY Italian patient was investigated by amplification, subcloning, and sequencing of specific exonic sequences from genomic DNA samples. A homozygous mutation, consisting of a 518-basepair (bp) deletion combined with a 469-bp insertion, was identified in the CYP17 gene of the patient. The deletion spans much of exon II, the whole intron 2, and a portion of exon III. A part (156 bp) of the inserted sequence shows 95.5% identity to the nuclear antigen-binding site on Marek disease virus DNA and sequences found in rearranged mitochondrial DNA of rat hepatoma cells. A similar degree of sequence identity (99%) was also found between the above sequences and part of the lac operon of E. coli. The inserted sequence is lacking the BamHI site in intron 2 of CYP17 and contains an in-frame stop codon (TAA). Thus, the mutated gene encodes a truncated nonfunctional steroid hydroxylase, giving rise to symptoms associated with complete combined 17 alpha-hydroxylase/17,20-lyase deficiency. The family history revealed that the patient is the child of a consanguineous marriage and has two genotypically and phenotypically female sisters also suffering from symptoms of the disease. Investigation of genomic DNA from these sisters revealed that in each case both CYP17 alleles contained the same mutation. On the other hand, the parents were found to be heterozygous for this mutation. The insertion could not be found in DNA from normal individuals or in the CYP17 gene of other Italian patients with the 17 alpha-hydroxylase deficiency syndrome.(ABSTRACT TRUNCATED AT 250 WORDS)     

kitl非编码区突变导致RNA剪切异常的小鼠

本文主要采用RT-RCR技术从kitl1-bao纯合子和正常C57BL/6(B6)小鼠总RNA中扩增出kitl基因片段,测序后与GenBank(登录号:NM.013598)序列比对,找到mRNA上突变部位。PCR扩增kitl基因组DNA上对应部位进一步测序验证。结果发现kitl1-bao突变纯合子kitl基因mRNA缺少第8号外显子。在基因组DNA上kitl基因第8号内含子第2个碱基由T转换为C,是引起mRNA剪接错误的原因     

Factor IXMadrid 2: a deletion/insertion in factor IX gene which abolishes the sequence of the donor junction at the exon IV-intron d splice site.

DNA from a patient with severe hemophilia B was evaluated by RFLP analysis, producing results which suggested the existence of a partial deletion within the factor IX gene. The deletion was further localized and characterized by PCR amplification and sequencing. The altered allele has a 4,442-bp deletion which removes both the donor splice site located at the 5' end of intron d and the two last coding nucleotides located at the 3' end of exon IV in the normal factor IX gene; this fragment has been replaced by a 47-bp sequence from the normal factor IX gene, although this fragment has been inserted in inverted orientation. Two homologous sequences have been discovered at the ends of the deleted DNA fragment.     

Seven novel Tay-Sachs mutations detected by chemical mismatch cleavage of PCR-amplified cDNA fragments.

Total RNA was isolated from cultured fibroblasts from 12 unrelated patients with Tay-Sachs disease, an autosomal recessive disorder due to beta-hexosaminidase A deficiency. beta-Hexosaminidase mRNA was amplified by cDNA-PCR in four overlapping segments spanning the entire coding sequence. In two patients, abnormal size cDNA-PCR fragments in which exons were removed resulted from splicing mutations that were characterized at the genomic DNA level: both were G to A transitions, at the first position of intron 2 and at the fifth position of intron 4. Five other mutations have been identified by cDNA-PCR chemical mismatch analysis and direct sequencing of an amplified fragment containing the mismatch site. One missense mutation alters the codon for Ser210 to Phe in exon 6 and the other one alters the codon for Arg504 to Cys in exon 13. A 3-bp deletion results in the deletion of a phenylalanine residue in exon 8. Two nonsense mutations in exon 3 (Arg137 to stop) and in exon 11 (Arg393 to stop) are associated with a marked decrease of mRNA abundance, probably because they result in mRNA instability. Three of the six single base mutations involve the conversion of a CpG dinucleotide in the sense strand to TpG. These results demonstrate the extreme molecular heterogeneity of mutations causing Tay-Sachs disease. The procedure described in this paper allows the rapid detection of any type of mutation, except those impairing the promoter function. Applicable even to patients with splicing or nonsense mutations and very low mRNA abundance, it has therefore a potentially broad application in human genetics, for both diagnostic and fundamental purposes.     

Molecular analysis of five independent Japanese mutant genes responsible for hypoxanthine guanine phosphoribosyltransferase (HPRT) deficiency

Five independent mutations in the hypoxanthine guanine phosphoribosyltransferase (HPRT) gene were identified in a partially HPRT deficient patient with gout and in four Lesch-Nyhan patients. Using the polymerase chain reaction (PCR) technique coupled with direct sequencing, the nucleotide sequences of the entire HPRT coding region amplified from the cDNA and also of each exon amplified form the genomic DNA were analyzed. Three independent point mutations in the coding region were detected in the partially HPRT deficient patient (Case 1) and in two Lesch-Nyhan patients (Case 2 and 3), resulting in single amino acid substitutions. The family study of Case 3, utilizing a PvuII restriction site created in the mutant gene, indicated that the mother was a heterozygote, and a sister and a fetal brother had inherited the normal HPRT gene from the mother. In two other mutants causing Lesch-Nyhan syndrome, a portion of the HPRT gene was deleted, and RNA splicing was missing in both mutants. A 4-bp deletion at the 5 end of exon 4 resulted in formation of three different types of abnormal mRNA (Case 4). The other mutant (Case 5) produced abnormal mRNA including 26bp of intron 8 instead of the deleted 58bp at the 5 end of exon 9, because of a 74-bp deletion from intron 8 to exon 9.