Nonconservative utilization of aldolase A alternative promoters

Recently, analysis of the sequence and expression of the human aldolase A gene revealed the unique arrangement of three tandem promoters and exons preceding a common coding sequence. A muscle-specific promoter (M) and two flanking widely used promoters (N and H) produce mRNA species which, in their mature forms, differ only in the sequence of their 5'-untranslated regions. We have isolated and investigated the expression of a mouse aldolase A gene. This mouse gene represents a functional gene by sequence analysis, recombinational screening, and by transfection into C2C12 cells. Although there is a high degree of sequence similarity between the mouse and the human gene in the region of the alternative first exons, we have been unable to detect a functional utilization of the 5'-most promoter (N) in the mouse. Steady state mRNAs isolated from a variety of adult tissues and cultured cells were analyzed by RNase protection and primer extension to identify first exon utilization. Consistent with previous reports, exon M is found only in skeletal muscle and exon H, the "housekeeping" exon, is utilized in every tissue where aldolase A is expressed. Under identical conditions we fail to see any evidence of the N exon. Therefore, although sequence homology exists between rodents and primates in the N region, the absence of selective pressure to preserve its primate pattern of expression may have resulted in functional promoter extinction.     

Transcriptional activation of lck by retrovirus promoter insertion between two lymphoid-specific promoters

p56lck, a member of the src family of cytoplasmic tyrosine protein kinases, is expressed primarily in lymphoid cells. Previous RNase protection data demonstrated the existence of at least two lck mRNAs (type I and type II) with different 5' untranslated regions in most T cells. These have been found here to arise from two separate promoters. S1 nuclease analysis and primer extension were used to locate the site of initiation of type I lck mRNA. The nucleotide sequence of the region upstream of this start site contains no classical promoter motifs. A cDNA clone of type II lck mRNA was isolated. The promoter of this mRNA must be more than 10 kilobases upstream of the type I promoter region. In two murine thymoma cell lines, LSTRA and Thy19, lck is expressed at elevated levels as a result of Moloney murine leukemia virus retrovirus promoter insertion. p56lck is encoded in these cells by a hybrid virus-lck mRNA containing the 5' untranslated region of Moloney virus mRNA. The structures and the sites of integration of the proviruses upstream of lck in these cells were examined by molecular cloning and Southern analysis. A truncated and rearranged provirus, flanked by 554 nucleotides (nt) of duplicated cellular sequences, was found 962 nt upstream of the start site for type I lck mRNA in LSTRA cells. What appears to be a Moloney mink cytopathic focus-forming provirus was found between 584 to 794 nt upstream of the start site for type I lck mRNA in Thy19 cells. Thus in both tumor cell lines, viral DNA is present between the promoters for type I and type II lck mRNAs. Comparison of the sequences of the 5' ends of the lck and c-src genes suggests that divergence of these two genes involved exon shuffling and that a homolog of the neuronal c-src(+) exon is not present in lck.     

The cyclic nucleotide phosphodiesterase gene of Dictyostelium discoideum contains three promoters specific for growth, aggregation, and late development.

The cyclic nucleotide phosphodiesterase (phosphodiesterase) plays essential roles throughout the development of Dictyostelium discoideum. It is crucial to cellular aggregation and to postaggregation morphogenesis. The phosphodiesterase gene is transcribed into three mRNAs, containing the same coding sequence connected to different 5' untranslated sequences, that accumulate at different times during the life cycle. A 1.9-kilobase (kb) mRNA is specific for growth, a 2.4-kb mRNA is specific for aggregation, and a 2.2-kb mRNA is specific for late development and is only expressed in prestalk cells. Hybridization of RNA isolated from cells at various stages of development with different upstream regions of the gene indicated separate promoters for each of the three mRNAs. The existence of specific promoters was confirmed by fusing the three putative promoter regions to the chloramphenicol acetyltransferase reporter gene, and the analysis of transformants containing these constructs. The three promoters are scattered within a 4.1-kilobase pair (kbp) region upstream of the initiation codon. The late promoter is proximal to the coding sequence, the growth-specific promoter has an initiation site that is 1.9 kbp upstream of the ATG codon, and the aggregation-specific promoter has an initiation site 3 kbp upstream.     

Human acyl-CoA:cholesterol acyltransferase-1 (ACAT-1) gene organization and evidence that the 4.3-kilobase ACAT-1 mRNA is produced from two different chromosomes

Acyl-CoA:cholesterol acyltransferase (ACAT) plays important roles in cellular cholesterol homeostasis. Four human ACAT-1 mRNAs (7.0, 4.3, 3.6, and 2.8 kilobases (kb)) share the same short 5'-untranslated region (exon 1) and coding sequence (exons 2-15). The 4.3-kb mRNA contains an additional 5'-untranslated region (1289 nucleotides in length; exons Xa and Xb) immediately upstream from the exon 1 sequence. One ACAT-1 genomic DNA insert covers exons 1-16 and a promoter (the P1 promoter). A separate insert covers exon Xa (1277 base pairs) and a different promoter (the P7 promoter). Gene mapping shows that exons 1-16 and the P1 promoter sequences are located in chromosome 1, while exon Xa and the P7 promoter sequence are located in chromosome 7. RNase protection assays demonstrate three different protected fragments, corresponding to the 4.3-kb mRNA and the two other mRNAs transcribed from the two promoters. These results are consistent with the interpretation that the 4.3-kb mRNA is produced from two different chromosomes, by a novel RNA recombination mechanism involving trans-splicing of two discontinuous precursor RNAs.     

The multiple untranslated first exons and promoters system of the oestrogen receptor gene in the brain and peripheral tissues of the rat and monkey and the developing rat cerebral cortex

Recent studies on the human oestrogen receptor (ER) gene have revealed the complex system with the multiple untranslated first exons and promoters in the ER gene expression. Little information is however available on the system in the ER gene of the rat or nonhuman primate. The rat genomic library was first screened by the rat ER cDNA (0–1) probe. One of the four positive clones (λ rEgEl) was subcloned and sequenced. The nucleotide sequence was found to contain the exon 0, the intron 0, and the exon 1 with its 3′-ends. The novel untranslated first exons, the exon ON and the exon OS, were further identified. These results indicated the presence of at least four subtypes of the rat ER mRNAs; the messages transcribed from promoter P-0 (ER mRNA (0–1)), putative promoter P-1 (ER mRNA (1–1)), promoter P-ON (ER mRNA (ON-1)) and promoter P-OS (ER mRNA (OS-1)). The P-O- or P-1 driven message (0–1) or (1–1) appeared to be expressed most strongly in major oestrogen central- (anterior pituitary, AP, hypothalamus–preoptic area, HPOA, and amygdala, AMG) and peripheral targets (uterus and ovary). The message (ON-1) was strongly expressed in the liver and kidney, but not in the HPOA, AMG, cerebral cortex, CC, and cerebellum, Ce. The OS-1 message was expressed variably but generally in the tissues examined except for the CC and Ce. Thus, the region- and tissue specific expression of the rat ER gene is likely to be regulated by the multiple untranslated exons and promoters system. Furthermore, when the ER mRNA subtypes were examined in the rat neonatal CC where the ER protein level rose transiently, considered as a model for the development of the ER or progestin receptor A and B isoforms, the expression of the ER mRNAs seemed to be differential postnatally, implicating some stage dependent usage of the promoters in the development. In the monkey, we identified the untranslated first exon OS, the homologue of the rat exon OS. Interestingly, the exon C was found to consist of two different exons, the exon OK and the exon OG. By the alternative usage of the promoters and the alternative splicing, at least six ER mRNA subtypes, that is, ER mRNAs (0–1), (1–1), (OS-1), (OS-OG-1), (OK-1) and (OK-OG-1) were identified in the monkey tissues. These messages were also differentially distributed in the monkey brain and other tissues. It was noteworthy that the P-OK driven messages were expressed almost exclusively in the monkey liver. These results have suggested that the systems of the multiple untranslated first exons and promoters and the alternative splicing are involved in the regulation of the region- and tissue specific expression of the ER gene in the brain and peripheral tissues of the rat and monkey. Stage-related usage of the promoters was also suggested in the ER gene expression in the CC of the postnatal rat in development.