Cloning and characterization of human tissue inhibitor of metalloproteinases-3.

The tissue inhibitors of metalloproteinases (TIMPs) comprise a family of proteins, of which two members have so far been described in humans. We have cloned and sequenced a third human TIMP (hTIMP-3) from phorbol ester-differentiated THP-1 cells stimulated with bacterial lipopolysaccharide. The open reading frame encodes a 211-amino-acid precursor including a 23-residue secretion signal. The mature polypeptide has a calculated molecular weight of 21.6 kD and includes an N-linked glycosylation site near the carboxyl terminus. The protein is quite basic, having a predicted isoelectric point of 9.04. We have mapped the single gene encoding human TIMP-3 to chromosome 22. By Northern analysis, transcripts for TIMP-3 were identified in a broad cross-section of tissues examined from both embryonic and adult origin. In all tissues except the placenta, the predominant transcript was 5.0 kb in size, with minor bands around 2.4 and 2.6 kb comprising no more than about 10% of the signal. In the placenta, the smaller bands accounted for close to 50% of the signal. Human TIMP-3 shows slightly closer amino acid sequence similarity to TIMP-2 (44.3%) than to TIMP-1 (38.4%), but is most closely related to a recently reported chicken TIMP, chIMP-3 (80.8% amino acid; 77.7% nucleic acid similarity.

Tissue-specific enhancer of the human glycoprotein hormone alpha-subunit gene: dependence on cyclic AMP-inducible elements.

We identified and characterized elements which confer tissue specificity and cyclic AMP (cAMP) responsiveness to the human glycoprotein alpha-subunit gene. An enhancer containing an 18-base-pair repeat conferred cAMP responsiveness in a non-tissue-specific fashion. DNase I protection assays revealed DNA-binding factors that bound to this element in both placental and nonplacental cells. It also enhanced the alpha-subunit promoter in a tissue-specific manner but had a negligible effect on a heterologous promoter. A unique element found upstream of this enhancer had no independent activity but, in combination with the cAMP-responsive enhancer, distinctly increased the tissue-specific activity of both the alpha-subunit promoter and a heterologous promoter. A factor that bound to this upstream element was found in placental but not nonplacental cells. We conclude that this novel element acts, perhaps through a specific trans-acting factor, in concert with a cAMP-responsive enhancer to confer tissue specificity to the alpha-subunit gene.

A cloned chromogranin A (CgA) cDNA detects a 2.3Kb mRNA in diverse neuroendocrine tissues.

CgA is a 72Kd protein of unknown function that is present in many neuroendocrine tissues and co-secreted with their resident hormones. We prepared a cDNA library to the mRNA from CgA-producing human medullary thyroid carcinoma (MTC) cells in the expression vector lambda gt11. The library was screened with a panel of one polyclonal and two monoclonal antibodies to CgA. The specificity of the antibodies for CgA was demonstrated by immunoassay, immunohistology, and immunoprecipitation of the in vitro translation products of mRNA from CgA-producing tissues. A chromogenic second antibody identified five immunoreactive clones. Their cDNA inserts were isolated after EcoRI digestion and agarose gel electrophoresis. These cDNAs were 32P-labelled and used as probes in Northern hybridization studies. An mRNA of approximately 2.3Kb was detected with the cDNA probes in human cell lines from MTC and lung cancers that were shown to produce CgA and in human pheochromocytoma and bovine adrenal medulla tissue. To confirm its identity, one of the putative CgA cDNAs was subcloned into a plasmid and was used to hybridization-arrest the in vitro translation of CgA mRNA. These studies demonstrate the cloning of cDNAs which hybridize with CgA mRNA from diverse neuroendocrine tissues.

Methylation analysis of a plasmid containing a mammalian cell cycle regulatory sequence after transient transfection into the host cell.

A hamster genomic sequence containing a cell cycle regulatory sequence derived from a histone H3.2 gene was transfected into K12 hamster fibroblasts in the form of plasmid DNA prepared from dam+ E. coli. Analysis of the plasmid DNA recovered 72 hr after the transfection revealed that it was resistant to Mbol but was sensitive to Dpn 1 enzyme digestion, suggesting that this plasmid had retained its dam E. coli methylated sites and was therefore unable to undergo replication following transfection into homologous host cells. These results were discussed with relation to a previously described yeast cell cycle regulatory sequence which was functionally linked to an autonomous replicating sequence and was located near a yeast H2B gene.

Use of a cell cycle mutant to delineate the critical period for the control of histone mRNA levels in the mammalian cell cycle.

Temporal analysis of DNA replication and histone mRNA accumulation in a hamster fibroblast cell cycle mutant (K12) showed that histone mRNA accumulates periodically during the cell cycle and reaches its highest level in the S phase. The direct correlation between the initiation of DNA synthesis and the accumulation of histone mRNA to high levels in S phase demonstrated the strict interdependence of these two events. Moreover, a critical period necessary for histone mRNA accumulation occurred late in G1 phase. If cells were incubated at the nonpermissive temperature during this critical period, the amount of histone mRNA remained at the basal level. Transcription rate measurements indicated that the triggering of histone mRNA synthesis occurred in late G1 and this mRNA was synthesized at its maximal rate 3 to 5 h before its peak of accumulation. However, if cells were prohibited from synthesizing DNA as a consequence of the temperature-sensitive block in G1, the synthesis of histone mRNA was not initiated.

Transcriptional regulation of two genes specifically induced by glucose starvation in a hamster mutant fibroblast cell line.

This report concerns the characterization of the RNA transcripts encoded by two cDNA sequences p4A3 and p3C5, derived from a hamster temperature-sensitive mutant cell line K12. Using the two cDNA sequences as hybridization probes, we show that they occur as single copy genes in the hamster genome and encode for RNA transcripts which are highly inducible in K12 cells at 40.5 degrees C. After incubation at 40.5 degrees C for 16 h, there is a 10-fold increase in the p4A3 and p3C5 mRNA levels, reaching a final concentration of about 1% of the cytoplasmic polyadenylated RNA. We demonstrate that the kinetics of transcription of p4A3 and p3C5 directly parallel the accumulation of the mRNA levels at 40.5 degrees C. Thus, our data indicate that the expression of these two genes are primarily regulated at the transcriptional level. In addition, there is a 3- to 4-fold increase in the p4A3 and p3C5 mRNA levels when the cells are specifically starved of glucose. This implies that the expression of these two genes are stringently regulated by the availability of glucose in the culture medium. The relationship between the cDNA clones and two glucose-regulated proteins which are overproduced in K12 cells at 40.5 degrees C is discussed.

Characterization of a cell cycle mutant derived from hamster fibroblast: reversion analysis.

K12 is a temperature-sensitive (ts) mutant cell line derived from Chinese hamster fibroblasts. When incubated at the nonpermissive temperature, K12 cells exhibit the following properties: (a) the cells cannot initiate DNA synthesis;o (b) the synthesis of cytosol thymidine kinase is suppressed; and (c) the synthesis of three cellular proteins of molecular weights 94, 78, and 58 kdaltons is greatly enhanced. Here we characterize a spontaneous revertant clone, R12, derived from the K12 cells. We selected the revertant clone for its ability to grow at the nonpermissive temperature. Our results indicate that all the traits which constitute the K12 mutant phenotype are simultaneously reverted to the wild type in the revertant cell line, suggesting that the ts mutation of the K12 cells is of regulatory nature and exerts multiple effects on the expressed phenotypes.

Coupling of histone and DNA synthesis in the somatic cell cycle.

The coupling of histone and DNA synthesis was examined in the temperature-sensitive hamster fibroblast cell line K12. By monitoring total cellular histone synthesis at various times after quiescent cells were stimulated to proliferate at permissive and nonpermissive temperatures, a direct correlation was found between the rates of DNA and histone synthesis. Furthermore, when DNA synthesis was blocked by the K12 mutation, histone synthesis was reduced to the basal rate.

Independent activation of the acetylcholine receptor from Torpedo californica at two sites.

Membrane vesicles enriched in acetylcholine receptor were prepared from the electroplax tissue of Torpedo californica. The receptor was reduced with dithiothreitol to expose a sulfhydryl group near the ligand binidng site and then treated in one of the following ways: (1) affinity alkylated treated in one of the following ways: (1) affinity alkylated with bromoacetylcholine, a receptor activator, (2) affinity alkylated with maleimidobenzyltrimethylammonium, a receptor inhibitor, or (3) reoxidized to the native state with dithiobis(2-nitrobenzoate). The affinity labels blocked half of the binding sites for alpha-bungarotoxin. The toxin sites not protected by the affinity labels were protected by carbamylcholine based on studies of toxin binding kinetics. The functional response of native and affinity-alkylated receptors was measured by a sodium ion flux procedure. In the absence of added cholinergic activators, only slow ion flux was observed. In the presence of carbamylcholine, a receptor activator, both native and modified membranes showed the increased sodium flux associated with functional receptors. The concentration of carbamylcholine required for a 50% maximal response was higher in the affinity-labeled membranes. Preincubation of the membranes with carbamylcholine blocked the increased ion flux, indicating that desensitization could be induced. The results provide evidence for the existence of two functional sites on the acetylcholine receptor. Each site corresponds to a bungarotoxin binding site and can be independently activated and desensitized.