Construction of rat aldolase C expression plasmid and the hybrid formation between rat aldolase C and human aldolase A or B co-expressed in Escherichia coli

Rat aldolase C cDNA was inserted in an Escherichia coli expression vector to construct the rat aldolase C expression plasmid, pRAC42. This plasmid produces active rat aldolase C in the transfected E. coli host cells. The characteristics of the purified enzyme, e.g. mol. wt, electrophoretic mobilities and kinetic parameters, are indistinguishable from those of authentic rat brain aldolase C. Three different tetrameric hybrid forms, C3A, C2A2 and CA3, in addition to C4 and A4, were found to be produced in the host cell when E.coli was co-transfected with expression plasmids for rat aldolase C and for human aldolase A. Similarly, the hybrid forms, C3B, C2B2 and CB3, in addition to C4 and B4, were also produced in the cells when co-transfected with the plasmids for rat aldolase C and for human aldolase B.     

The structure of the rat ameloblastin gene and its expression in amelogenesis

Ameloblastin (also designated amelin and sheathlin) is an enamel matrix protein expressed within the ameloblast lineage. In this study we analyzed the structure of the rat ameloblastin gene and characterized its subtypes. The promoter sequence contains several E-box-like elements, and consensus sequences for AP1 and SP1. The gene is about 6 kb in length and contains 12 exons. Exon 1 was mapped by primer extension and encodes 90 bp of 5' untranslated leader sequence, followed by the coding sequences of exon 2 (309 bp), alternatively spliced exon 3a (45 bp), exon 3b (198 bp), exon 4 (36 bp), exon 5 (60 bp), exon 6 (45 bp), exon 7 (150 bp), and exon 8 (448 bp) containing coding sequence (426 bp) and 3' untranslated sequence (22 bp), followed by exon 9 (39 bp); exon 10 (143 bp); exon 11 (342 bp); and exon 12. Exon 3a, encoding YEYSLPVHPPPLPSQ, has a potential SH3 binding domain. Analysis of ameloblastin subclones showed that exon 3a and 11 were potential alternative splicing sites, producing 4 types of ameloblastin mRNA, from which ameloblastin I and II could be translated. Using in situ hybridization, immunohistochemistry, Western blot and RT-PCR methods we found that ameloblastin II, containing exon 3a, was more strongly expressed at the late maturation stage of ameloblasts than at the secretory stage, while a common probe for both ameloblastin subtypes showed wide expression throughout the presecretory, secretory and postsecretory stages. From the above results we propose that ameloblastin II plays an important role in the mineralization of ameloblasts during the maturation stages.     

Human aldolase isozyme gene: the structure of multispecies aldolase B mRNAs.

A complete nucleotide sequence of human aldolase B mRNA was determined with a recombinant cDNA (pHABL120-3). The cDNA insert was composed of 1,652 bases excluding poly(A) tail and the sequence was consistent with the previous results reported by others. However, S1 nuclease mapping and subsequent genomic analysis allowed us to know that the clone possesses two more sites corresponding to 5'-termini in the 5'-noncoding region and another site of polyadenylation in the 3'-noncoding region. In fact, the major aldolase B mRNA species occupying 90% of the total mRNAs initiated at the predominant position corresponding to the position around -82 of the 5'-noncoding sequence in pHABL120-3 and terminated at the distal polyadenylation site. Second species accounting for 9% of the mRNAs initiated at the same site and terminated at the proximal polyadenylation site. The remainings have a longer 5'-noncoding sequence which starts from further upstream region of the major one and pHABL120-3 corresponds to one of these largest clones.     

Structure of chicken aldolase C mRNA and its expression in the liver and brain during development

Chicken aldolase B (liver-type) and C (brain-type) cDNAs were isolated and their nucleotide sequences determined. Southern blot analysis of chicken genomic DNA using the fragments of aldolase C cDNA suggested that the aldolase C gene is a single-copy gene. The quantification by Northern blot analysis of aldolase B and C mRNAs in the chicken liver and brain during development showed that in the liver, the B gene was progressively activated, while C gene expression was extinguished reciprocally. In the brain, the B gene was silent throughout the development, while the C gene was activated progressively, reaching a product level of more than 20-fold that of the 7-day-old embryo.     

DNA methylation and the regulation of aldolase B gene expression

DNA methylation was studied as a potential factor for the regulation of tissue-specific and developmentally specific expression of the rat aldolase B gene. We examined cytosine methylation in the HpaII and HhaI recognition sequences in the aldolase B gene in aldolase expressing and nonexpressing tissues and cells. Out of the 15 methyl-sensitive restriction sites examined, the sites in the 3'-half and 3'-flanking regions were found to be heavily methylated in all the tissues or cells, regardless of the level of aldolase B gene expression. However, the methylation pattern in the region immediately upstream and in the 5'-half of the gene exhibited tissue-specificity: the site located about 0.13 kb upstream of the cap site (just next to the CCAAT box), and the sites in the first intron (intron 1) were heavily methylated in nonexpressing cells and tissues (ascites hepatoma AH130 and brain), whereas those in an expressing tissue (liver) were considerably less methylated. These results suggest that cytosine methylation at the specific sites in the 5'-flanking and 5'-half regions of the gene is associated with repression of the gene activity. However, the gene is still substantially methylated in the fetal liver on day 16 of gestation, when it is in a committed state for rapid activation in the period immediately afterwards (Numazaki et al. (1984) Eur. J. Biochem. 152, 165-170). This suggests that demethylation of the methylated cytosine residues in the specific gene region is not necessarily required before activation of the gene during development, but it may occur along with or after the activation.     

Neuronal expression of enhanced green fluorescent protein directed by 5' flanking sequences of the rat aldolase C gene in transgenic mice

The rat aldolase C gene encodes a glycolytic enzyme strongly expressed in adult brain. We previously reported that a combination of distal and proximal 5' flanking sequences, the A+C+0.8 kilobase (kb) pairs fragments, ensured high brain-specific expression in vivo (Skala et al. 1998). We show here that the expression pattern conferred by these sequences, when placed in front of the chloramphenicol acetyltransferase (CAT) or the enhanced green fluorescent protein (EGFP) reporter genes in transgenic mice, is similar to the distribution of the endogenous mRNA and protein. Double immunostaining for neuronal or glial cell-specific markers and for the EGFP protein indicates that the A+C+0.8 kb genomic sequences from the rat aldolase C gene direct a predominant expression in neuronal cells of adult brain.     

大鼠肝癌中α—抑制因子3基因表达及基因结构的...

The expression and structure of alpha 1-inhibitor 3 (alpha 1-I3) gene were investigated in 16 primary rat hepatomas induced by diethylnitrosamine. In most tumor samples (75%, 12/16), the expression of alpha 1-I3 gene manifested markedly diminished or undetectable level of alpha 1-I3 mRNA. Further study indicated that the abnormal expression of alpha 1-I3 gene in the hepatomas examined might be due to, at least in part, the gene hypermethylation, insertion of repeat sequence(s) or base substitutions at the recognition sequences of some restriction endonucleases which caused certain alteration in the gene structure. The significance of alpha 1-I3 as an endogenous antitumor factor in hepatocarcinogenesis was also discussed.     

Neuronal expression of enhanced green fluorescent protein directed by 5' flanking sequences of the rat aldolase C gene in transgenic mice.

The rat aldolase C gene encodes a glycolytic enzyme strongly expressed in adult brain. We previously reported that a combination of distal and proximal 5' flanking sequences, the A + C + 0.8 kilobase (kb) pairs fragments, ensured high brain-specific expression in vivo (Skala et al. 1998). We show here that the expression pattern conferred by these sequences, when placed in front of the chloramphenicol acetyltransferase (CAT) or the enhanced green fluorescent protein (EGFP) reporter genes in transgenic mice, is similar to the distribution of the endogenous mRNA and protein. Double immunostaining for neuronal or glial cell-specific markers and for the EGFP protein indicates that the A + C + 0.8 kb genomic sequences from the rat aldolase C gene direct a predominant expression in neuronal cells of adult brain.     

Purification of aldolase C from rat brain and hepatoma.

An isolation procedure for rat brain aldolase C has been developed which also permits the isolation of aldolase C from experimental hepatomas. Certain enzymatic properties (specific activity and Michaelis constant towards the two specific substrates: fructose 1,6-biphosphate and fructose 1-phosphate) and physico-chemical properties (molecular weight, N-terminal amino-acid) of the two enzymes have been studied and compared. Moreover, an amino-acid analysis has been carried out for rat brain aldolase C. Within experimental errors, the two enzymes appear to be identical.