Cloning and expression of a mouse adenine phosphoribosyltransferase gene

A functional mouse adenine phosphoribosyltransferase (APRT) gene was identified and cloned by screening a mouse sperm genomic DNA library in lambda Charon 4A. The probe utilized for screening was a restriction fragment encoding much of the hamster APRT gene. Six recombinants that hybridized with the probe were identified, and after digestion with restriction enzymes EcoRI and PvuII revealed three different patterns of digestion for each enzyme. Of the six recombinants, five representing two of the restriction patterns possessed transforming activity. A sixth recombinant, which has a unique restriction pattern, lacks transforming activity but hybridizes well with hamster APRT coding sequences and is a possible candidate for a pseudogene. We used three criteria for conclusively identifying the mouse APRT genes. (1) DNA from the recombinant lambda phage hybridizes with DNA encoding hamster APRT. (2) The recombinant lambda phages and their DNAs transform mouse, hamster and human APRT- cells to the APRT+ phenotype. (3) The hamster and human transformants display APRT activity that migrates with a mobility characteristic of mouse APRT and not of hamster or human. A 3.1-kb EcoRI-SphI restriction fragment which retains transforming activity has been subcloned into the plasmid pBR328. Comparison of restriction enzyme sites with those contained in a mouse APRT cDNA, coupled with loss of transforming activity after enzyme digestion, indicates that the mouse APRT gene is larger than 1.8 kb and contains at least three introns.     

Identification of two novel mutations in adenine phosphoribosyltransferase gene in patients with 2,8-dihydroxyadenine urolithiasis

Five mutations in the adenine phosphoribosyltransferase (APRT) gene have been described in Japanese patients with APRT deficiency. We investigated the APRT gene from three patients with APRT deficiency and two novel mutations, G133D and V84M, were determined.     

Identification of Two Novel Mutations in Adenine Phosphoribosyltransferase Gene in Patients with 2,8‐Dihydroxyadenine Urolithiasis

Five mutations in the adenine phosphoribosyltransferase (APRT) gene have been described in Japanese patients with APRT deficiency. We investigated the APRT gene from three patients with APRT deficiency and two novel mutations, G133D and V84M, were determined.     

Identification and characterization of a novel adenine phosphoribosyltransferase gene (ZmAPT2) from maize (Zea mays L.).

Adenine phosphoribosyltransferase (APRT) is the key enzyme that converts adenine to adenosine monophosphate (AMP) in the purine salvage pathway. It was found that several different forms of APRT gene exist in plants, but no APRT gene in maize has been reported up to now. In this study, a novel maize APRT gene was cloned and characterized through a combination of bioinformatic, RT-PCR and RACE strategies. The full length of APRT cDNA sequence is 1202 nucleotides, with an ORF encoding 214 amino acid residues. Alignment of the deduced protein with that of other plant APRT genes indicates that the new gene is the form 2 of maize APRT, thus it was named ZmAPT2. Through basic local alignment search tool, search in the genomic survey sequence database of MaizeGDB, the putative genomic sequence of ZmAPT2 was obtained. Comparison of the cDNA and genomic sequence of the ZmAPT2 gene revealed that it contained seven exons and six introns. The locations of the introns within the maize ZmAPT2 coding region were consistent with those in the previously isolated APRTs of arabidopsis and rice. RT-PCR analysis showed that ZmAPRT was constitutively expressing in different organs under high temperature and salt stresses. Southern blot analysis indicated that at least three APRT genes existed in maize genome. These results confirmed that the novel maize ZmAPT2 gene was truly identified, and its potential role in maize growth and development was discussed.     

水稻基因APRT的克隆及其与温敏核雄性不育的关系

在拟南芥中腺嘌呤磷酸核糖转移酶基因(APRT)突变导致植株雄性不育.本文首次报道从水稻(Oryza sativa subsp.indica)中克隆了基因APRT(GenBank登录号AY238894),并将其定位于水稻第4染色体的一个BAC克隆(AL606604)的58 000 bp至63 000 bp区域.该基因长4 220 bp(起始密码子至终止密码子),含7个外显子、6个内含子,编码的APRT蛋白长212个氨基酸残基,与其他物种来源的APRT序列存在很高的同源性.与大麦、小麦、拟南芥1型及其2型的该蛋白同源性分别为54.9%、54.9%、49.6%和59.5%.经保守结构域搜索发现该蛋白中存在APRT催化结构域.从DNA、mRNA两个水平分析了该基因与水稻温敏核雄性不育(TGMS)的关系,结果表明:受温度诱导,水稻"安农S-1"APRT基因的表达变化可能与温敏核雄性不育表现型具相关性.     

A new location for the human adenine phosphoribosyltransferase gene (APRT) distal to the haptoglobin (HP) and fra(16)(q23)(FRA16D) loci

The human adenine phosphoribosyltransferase gene (APRT) was mapped with respect to the haptoglobin gene (HP) and the fragile site at 16q23.2 (FRA16D). A subclone of APRT and a cDNA clone of HP were used for molecular hybridization to DNA from mouse-human hybrid cell lines containing specific chromosome 16 translocations. The APRT subclone was used for in situ hybridization to chromosomes expressing FRA16D. APRT was found to be distal to HP and FRA16D and was localized at 16q24, making the gene order cen-FRA16B-HP-FRA16D-APRT-qter.     

Loss of heterozygosity and base substitution at the APRT locus in mismatch-repair-proficient and -deficient colorectal carcinoma cell lines.

We determined the nature of mutations occurring at the autosomal APRT locus in mismatch-repair-proficient and -deficient colorectal carcinoma cell lines. The analysis of mutations that result in APRT deficiency in a mismatch-repair-deficient strain of DLD-1 heterozygous for this locus enabled us to measure the rate of loss of the wild-type gene through deletion, recombination, or gene conversion as well as the rate of point mutation. The overall rate of mutation at the APRT locus in DLD-1 was elevated 100-fold compared with the mismatch-repair-proficient colorectal carcinoma cell line SW620. Loss of heterozygosity (LOH) at APRT accounted for only 4 to 9% of mutant strains derived from DLD-1, indicating a rate for these types of events of 4 x 10(-7) to 9 x 10(-7). In SW620 the rate of LOH at APRT was about 10-fold higher. LOH was not found at polymorphic markers within the same chromosome subband as APRT, indicating that only a limited portion of the chromosome was affected by these alterations. Chromosome painting of SWS620 mutants revealed that the loss of APRT occurred together with a substantial portion of the long arm of chromosome 16. Differences in the nature of base substitutions at APRT (e.g., the proportion of mutations resulting from transitions or transversions) in these tumor cell lines were also detected. There was also an important similarity---the presence of a mutant APRT gene with multiple base substitutions that may be the result of some sort of error-prone DNA synthesis.     

Homology dependence of targeted recombination at the Chinese hamster APRT locus.

Using simple linear fragments of the Chinese hamster adenine phosphoribosyltransferase (APRT) gene as targeting vectors, we have investigated the homology dependence of targeted recombination at the endogenous APRT locus in Chinese hamster ovary (CHO) cells. We have examined the effects of varying either the overall length of targeting sequence homology or the length of 5' or 3' flanking homology on both the frequency of targeted homologous recombination and the types of recombination events that are obtained. We find an exponential (logarithmic) relationship between length of APRT targeting homology and the frequency of targeted recombination at the CHO APRT locus, with the frequency of targeted recombination dependent upon both the overall length of targeting homology and the length of homology flanking each side of the target gene deletion. Although most of the APRT+ recombinants analyzed reflect simple targeted replacement or conversion of the target gene deletion, a significant fraction appear to have arisen by target gene-templated extension and correction of the targeting fragment sequences. APRT fragments with limited targeting homology flanking one side of the target gene deletion yield proportionately fewer target gene conversion events and proportionately more templated extension and vector correction events than do fragments with more substantial flanking homology.     

APT1, but Not APT2, Codes for a Functional Adenine Phosphoribosyltransferase in Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae has two separate genes (APT1 and APT2) that encode two potentially different forms of adenine phosphoribosyltransferase (APRT). However, genetic analysis indicated that only APT1 could code for a complementing activity. Cloning and expression of both the APT1 and APT2 genes in Escherichia coli showed that although discrete proteins (APRT1 and APRT2) were made by these genes, only APRT1 had detectable APRT activity. Northern and Western blot analyses demonstrated that only APT1 was transcribed and translated under normal physiological conditions in yeast. Phylogenetic analysis revealed that APRT1 and APRT2 are evolutionary closely related and that they arise from a gene duplication event. We conclude that APT1 is the functional gene in S. cerevisiae and that APT2 is a pseudogene.     

Genetic linkage but independent expression of functional HSV-1 tk and mammalian aprt genes after cotransfer to L cells

DNA-mediated gene transformation of mouse Ltk-aprt-hprt-cells was used to obtain stable, doubly selected transformants simultaneously expressing herpes virus thymidine kinase (TK) and mammalian adenine phosphoribosyltransferase (APRT). Cotransformants occurred at a frequency of 5 X 10(-6), a similar frequency for the transfer of the aprt marker has been previously observed. Isozyme and Southern blot analysis show that the TK and APRT expressed in these transformants resulted from gene transfer. For one stable cotransformant, [3H]thymidine [( 3H]TdR) selection against TK activity resulted in the loss of APRT activity as well, suggesting that these genes had become genetically linked together. Similarly selection against APRT expression resulted in the loss of a subset of the transferred herpes simplex virus tk genes. 5-Bromodeoxyuridine (BUdR) selected TK- variants differed from [3H]TdR selected TK- variants, in that they retained tk genes. However, BUdR-selected variants expressed full levels of APRT. Therefore, even though the transferred tk and aprt genes had become genetically linked together, they were, in this case, independently expressed since these cells were phenotypically TK- and APRT+.     

Cloning of a Drosophila melanogaster adenine phosphoribosyltransferase structural gene and deduced amino acid sequence of the enzyme

The Aprt locus of Drosophila melanogaster encodes the structural gene for adenine phosphoribosyltransferase (APRT). DNA cloned from microdissected salivary gland polytene chromosome region 62B7-12 was used in conjunction with chromosome walking and hybrid selection of mRNA to isolate the Aprt gene. Aprt lies at cytogenetic position 62B9 and is closely flanked by other genes of unknown function. Nucleotide sequencing shows that four APRT cDNAs have a common 5' terminus with an apparent cap consensus sequence but two different 3' sites of polyadenylation. The distribution of conserved amino acid sequences in APRT from vertebrates, insects and bacteria suggests that they may have shared a common ancestral gene for this ubiquitous enzyme.     

2,8-Dihydroxyadenine Urolithiasis: A Not So Rare Inborn Error of Purine Metabolism

Adenine phosphoribosyltransferase (APRT) deficiency is a rare inherited metabolic disorder that leads to the formation and hyperexcretion of 2,8-dihydroxyadenine (DHA) into urine. The low solubility of DHA results in precipitation and formation of urinary crystals and kidney stones. The disease can be present as recurrent urolithiasis or nephropathy secondary to crystal precipitation into renal parenchyma (DHA nephropathy). The diagnostic tools available, including stone analysis, crystalluria, and APRT activity in red blood cells, make the diagnosis easy to confirm when APRT deficiency is suspected. However, the lack of recognition of this metabolic disorder frequently resulted in a delay in diagnosis and treatment with grave consequences. The early recognition and treatment of APRT deficiency are of crucial importance to prevent irreversible loss of renal function. This review summarizes the genetic and metabolic mechanisms underlying DHA stones formation and chronic kidney disease, along with the issues of diagnosis and management of APRT deficiency. Moreover, we report the mutations in the APRT gene responsible for APRT deficiency in 51 French patients (43 families) including 22 pediatric cases (18 families) among the 64 patients identified in the biochemistry laboratories of Necker Hospital, Paris (1978–2013).     

A mutant allele common to the type I adenine phosphoribosyltransferase deficiency in Japanese subjects

Adenine phosphoribosyltransferase (APRT) deficiency is a genetic disorder which causes 2,8-dihydroxy-adenine urolithiasis. The estimated incidence of heterozygosity in Caucasian and Japanese populations is 1%. Mutant alleles responsible for the disease have been classified as APRT*Q0 (type I) and APRT* (type II). In our previous study, we demonstrated in APRT*J a single common base change which accounts for 70% of the Japanese mutants. The present report describes the analysis of an APRT*Q0 mutation in Japanese subjects. Two nucleotide substitutions common to all seven affected alleles from four unrelated subjects (three homozygotes and a heterozygote) were identified: G----A at nucleotide position 1453 and C----T at 1456. The G----A altered the amino acid Trp98 to a stop codon. The C----T did not alter Ala99. These point mutations were demonstrated by sequence analysis of polymerase chain reaction (PCR)-amplified genomic DNA and cDNA. The G----A change at 1453 results in the elimination of a PflMI site in the APRT gene. PflMI digests, which were used to confirm the G----A transition, can be useful in screening for this specific mutation.     

Common characteristics of mutant adenine phosphoribosyltransferases from four separate Japanese families with 2,8-dihydroxyadenine urolithiasis associated with partial enzyme deficiencies

Summary 2,8-Dihydroxyadenine urolithiasis associated with partial deficiencies of adenine phosphoribosyltransferase (APRT) has been found only among Japanese families. All Caucasian patients with the same lithiasis are completely deficient in this enzyme. Partially purified APRT from one of the Japanese families with the lithiasis associated with a partial deficiency of APRT had a reduced affinity for 5-phosphoribosyl-1-pyrophosphate (PRPP). In the present investigations, we have shown that this characteristic is common in mutant enzymes from all the four separate Japanese urolithiasis families associated with partial APRT deficiencies so far tested. The mutant enzymes also had several other characteristics in common including increased resistance to heat in the absence of PRPP and reduced sensitivity to the stabilizing effect of PRPP. These data suggest that these families have a common mutant allele (APRT ^* J) at the APRT gene locus.     

斑茅两个看家基因片段的克隆及其在基因芯片中的应用

根据已发表的同源基因序列,利用RT-PCR技术分离了斑茅(Erianthus arundinaceus)的GAPDH和APRT两个看家基因片段,用它们作为cDNA芯片阳性参照,以未经聚乙二醇(PEG)胁迫处理的斑茅叶片为对照,和PEG胁迫的4组材料同cDNA芯片进行杂交分析。杂交结果显示,GAPDH杂交的Cy5与Cy3平均信噪比(Signal/Noise,S/N)分别为56.12和60.8,APRT杂交的Cy5与Cy3平均信噪比分别为51.06和47.25,信噪比均很高;同时两个看家基因的杂交都显示出极强的信号,其中GAPDH的杂交信号值大于10000,APRT也在8000以上,杂交结果可靠。分析了PEG胁迫4个时段BADH与两个看家基因的表达,BADH的表达有明显变化,而看家基因表达均较稳定。上述结果表明所克隆的两个看家基因在斑茅中表达量高,且PEG胁迫下表达较为稳定,是基因芯片理想的阳性参照。