The first intron (intron I) of the human factor IX gene, which has been previously suggested of having an expression-augmenting activity, was systematically studied for its potential enhancer activity. When tested with the chloramphenicol acetyltransferase expression vector with a minimal factor IX promoter, subregions of intron I showed only marginal enhancing activities (1.7-1.9-fold enhancement at the highest). Smaller subregions encompassing nucleotides 5660-6350 of the intron sequence even showed some weak negative regulatory activities (approximately 50% suppression at the highest), while a cytomegalovirus enhancer sequence, which was used as the positive control, had a 7-fold enhancement. A set of three factor IX minigene expression vectors with the same factor IX promoter were then constructed: p-416FIXc which contained the factor IX cDNA, p-416FIXm1 which contained the factor IX cDNA with a largely truncated intron I, and p-416FIXm2 which contained the factor IX cDNA with the intron I sequence further truncated. The p-416FIXm1 and p-416FIXm2 constructs showed 7-9-fold higher expression activities than p-416FIXc. The elevated factor IX antigen levels agreed well with the grossly elevated factor IX clotting activity and mRNA levels. These results indicate that the expression enhancing activity of intron I is not due to specific enhancer elements present in the intron subsequences, but is due to functional splicing sequences present in the precursor mRNAs produced from the minigene constructs containing intron I. By being efficiently assembled into spliceosome complexes, transcripts with splicing sequences may be better protected in the nucleus from random degradations than those without such sequences.
Hemophilia B-Leyden is characterized by the gradual amelioration of bleeding after the onset of puberty. All Leyden phenotype mutations found to date lie within the Leyden-specific region, which spans roughly nt-40 to +20 in the 5' end of the human factor IX gene. With HepG2 cell nuclear extracts, the Leyden-specific region and its immediate neighboring region of the normal factor IX gene showed five DNase I footprints: FP-I (nt +4 to +19), FP-II (nt -16 to -3), FP-III (nt -27 to -19), FP-IV (nt -67 to -49), and FP-V (nt -99 to -77). Protein binding affinities of short oligonucleotides containing sequences of FP-I, FP-II, or FP-III were substantially reduced in the presence of Leyden phenotype mutations in these areas, correlating well with the negative effects of these mutations on factor IX gene expression. A Leyden phenotype mutation at nt -20 (T to A) caused a loss of both footprints FP-III and FP-II but generated a new footprint, FP-III' (nt -34 to -23), partially overlapping with FP-III, indicating mutation-dependent competitive protein binding at these sites. Although the FP-III' area contains an androgen responsive element-like sequence, the nuclear protein that binds at FP-III' is not androgen receptor. The protein was not recognized by anti-androgen receptor antibody and, furthermore, was present not only in liver but also in both androgen receptor-positive and androgen receptor-negative cells in electrophoretic mobility shift assays. The nuclear concentration of this protein increased significantly upon treatment of the HepG2 cells with testosterone. Its binding affinity to an oligonucleotide (-32sub) containing the FP-III' sequence was greatly reduced in the presence of exogenous androgen receptor, suggesting a possible interaction of this protein with androgen receptor. The affinities of both this protein and a protein which binds to FP-III (presumably HNF-4) to -32sub with a mutation at nt -26 were grossly lowered. These findings suggest that the amelioration of hemophilia B-Leyden with a mutation at nt -20 after puberty involves binding of a specific non-androgen receptor nuclear protein at FP-III' and it is able to substitute for the function of a protein bound at FP-III in the normal gene optimally through its elevated interaction with androgen receptor upon a surge of testosterone.(ABSTRACT TRUNCATED AT 400 WORDS)
Herbal preparations are widely available and often regarded by the public as harmless remedies for a variety of medical ailments. However, some of these products or their metabolites can cause adverse effects such as liver damage. In this case report a 53-year-old female taking Shou-Wu-Pian for 8 months presented with acute hepatitis. Histopathological assessment of liver tissue obtained by biopsy was consistent with a toxic reaction. Clinical and biochemical resolution was brought about following cessation of the drug. It is important for clinicians to consider Chinese herbal preparations as a potential cause of abnormal liver function test results.
To clarify the mechanism of production of des-gamma-carboxy (abnormal) prothrombin (DCP) by hepatocellular carcinoma (HCC), we measured the levels of vitamin K, DCP, immunoreactive prothrombin and the activity of gamma-glutamyl carboxylase in liver tissues from HCC patients and in the medium of cultured human hepatoma cells. There was no significant difference in vitamin K (K1, MK-4) contents between HCC and non-HCC cirrhotic liver tissues. The activity of gamma-glutamyl carboxylase per unit amount of endogenous microsomal prothrombin precursor was decreased in HCC tissue compared with non-HCC liver tissue (positive plasma DCP: 335 +/- 72 vs 372 +/- 67, negative plasma DCP: 370 +/- 84 vs 393 +/- 56 nmol/min per mg prothrombin precursor, P > 0.05), although the total incorporation of 14COOH into microsomal precursor protein was higher in the former. By contrast, levels of DCP and immunoreactive prothrombin in HCC tissue were greater (P < 0.05) than those in non-HCC cirrhotic liver tissue. Furthermore, production of large amounts of immunoreactive prothrombin was observed in human hepatoma cells huH-1 and huH-2, which produced large amounts of DCP. These results suggest that there was excessive synthesis of prothrombin precursors by human HCC tissue and hepatoma cell lines huH-1 and huH-2. Thus, excessive synthesis of prothrombin precursors seems to be the main mechanism of DCP production by HCC.
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