Candida glabrata metallothioneins. Cloning and sequence of the genes and characterization of proteins

Southern blot analysis has identified several metallothionein gene sequences in a human pathogenic yeast Candida glabrata. Two of these genes encoding proteins designated MT-I and MT-II have been cloned and sequenced. No introns were found in either of the genes. The complete primary structure of MT-II was also determined by protein sequencing methods. As isolated, MT-I and MT-II consist of 62 and 51 amino acids, respectively. The only residues predicted from the nucleotide sequence but not present in the isolated protein are the amino-terminal methionines in each sequence. MT-I contains 18 cysteines, 14 of which are present as Cys-X-Cys motifs and two additional cysteines in a Cys-X-X-Cys sequence. The sequence of MT-II contains 16 cysteinyl residues, 14 of which are in Cys-X-Cys sequences. Fluorescence spectroscopy indicates the presence of Cu(I)-thiolate bonds in both proteins. The binding stoichiometries are 11-12 for MT-I and 10 for MT-II. Under certain nutritional conditions, a truncated form of MT-II was also produced. Northern analysis of the total cellular RNA from copper-treated cells showed that both MT-I and MT-II genes are regulated by this metal ion in a concentration-dependent fashion. The concentrations of MT-II mRNA appeared to be higher than that of MT-I mRNA at all concentrations of copper sulfate tested. Both genes are inducible by silver but not by cadmium salts. Cadmium ions, however, are effective in reducing the control levels of both MT-I and MT-II mRNAs.     

Regulation, linkage, and sequence of mouse metallothionein I and II genes.

The mouse metallothionein II (MT-II) gene is located approximately 6 kilobases upstream of the MT-I gene. A comparison of the sequences of mouse MT-I and MT-II genes (as well as those of other mammals) reveals that the coding regions are highly conserved even at "silent" positions but that the noncoding regions and introns are extremely divergent between primates and rodents. There are four blocks of conserved sequences in the promoters of mouse MT-I, mouse MT-II, and human MT-IIA genes; one includes the TATAAA sequence, and another has been implicated in regulation by heavy metals. Mouse MT-I and MT-II mRNAs are induced to approximately the same extent in vivo in response to cadmium, dexamethasone, or lipopolysaccharide. Mouse MT-I and MT-II genes are regulated by metals but not by glucocorticoids after transfection into HeLa cells.     

Induction of hepatic metallothioneins determined at isoprotein and messenger RNA levels in glucocorticoid-treated rats.

Induction of metallothionein-I (MT-I) and metallothionein-II (MT-II) by glucocorticoids was determined by h.p.l.c. analysis of proteins and Northern-blot analysis of MT mRNAs. Rats were injected with dexamethasone (0.03-10 mumol/kg) and hepatic concentrations of MTs were determined 24 h later. In control rats, only MT-II was detected (9.4 +/- 2.5 micrograms/g of liver), whereas the hepatic concentration of MT-I was below the detection limit (5 micrograms of MT/g). Dexamethasone did not increase MT-I above the detection limit at any dosage tested, but MT-II increased to 2.5 times control values at dosages of 0.30 mumol/kg and higher. Time-course experiments indicated that MT-II reached a maximum at 24 h after a single dosage of dexamethasone and returned to control values by 48 h. To determine whether dexamethasone increased MT-I in liver, samples were saturated with 109Cd, after which the amount of 109Cd in MT-I and MT-II was determined. Results indicated that, by this approach, MT-I and MT-II could be detected in control rats, and there was approx. 1.8 times more 109Cd in MT-II than in MT-I. At 24 h after administration of dexamethasone (1 mumol/kg), there was a small increase in the amount of 109Cd bound to MT-I, whereas the amount of 109Cd bound to MT-II increased to more than 2 times control values. Northern-blot hybridization with mouse cRNA probes indicated that MT-I and MT-II mRNAs increased co-ordinately after administration of dexamethasone. Thus, although glucocorticoids increase both MT-I and MT-II mRNAs, MT-II preferentially accumulates after administration of dexamethasone.     

Human metallothionein MT-I and MT-II processed genes

Two intronless pseudogenes, corresponding to the human metallothionein MT-I and MT-II processed genes, have been isolated from a human genomic library. MT-I processed gene has accumulated a number of mutations including a nonsense mutation giving rise to a termination codon at amino acid position 21, and a single base deletion at amino acid position 47 causing a shift in the reading frame. MT-II processed gene is a full-length perfect copy of its corresponding mRNA except for a few mutations. Most of the mutations in MT-II processed gene are silent except that the amino acid glycine (GGT) at position 10 is changed to serine (AGT) due to a transition. Both MT-I and MT-II processed genes possess poly(A) sequences of 21 and 17 nucleotides, respectively, 3' to the consensus AATAAA sequence. While these genes are quite similar in their sequences at the 3'-untranslated region, they show less than 50% homology in the 5'-untranslated sequences. Two direct repeats of 16 and 18 nucleotides in length define the limits of the MT-I and MT-II processed genes, respectively, and have been confirmed by S1 nuclease mapping analysis. In both MT-I and MT-II processed genes these direct repeats towards the 5' end of the gene start with an AhaIII (TTTAAA) restriction site. Our studies suggest that these direct repeats are the results of the insertion site duplication.     

Metallothioneins I and II: neuroprotective significance during CNS pathology

Metallothioneins (MTs) constitutes a superfamily of highly conserved, low molecular weight polypeptides, which are characterized by high contents of cysteine (sulphur) and metals. As intracellular metal-binding proteins they play a significant role in the regulation of essential metals. The major isoforms of the protein (MT-I and MT-II) are induced by numerous stimuli and pathogens but most importantly their induction by metals is closely linked to the physiological metabolism of zinc and protection from the toxic affects following heavy metal exposure. Although the preservation of their genetic expression across animal phyla suggests that MTs may play an important physiological role, MT-I, II knock out (KO) mice survive to adulthood. In both central and peripheral nervous tissues, MT-I, II have neuroprotective roles, which are also induced by exogenous MT-I and/or MT-II treatment. Hence, MT-I, II may provide neurotherapeutic targets offering protection against neuronal injury and degeneration.     

PKCδ mediates Nrf2-dependent protection of neuronal cells from NO-induced apoptosis

A chemical inhibitor library of 84 compounds was screened to investigate the signaling pathway(s) leading to activation of Nrf2 in response to nitric oxide (NO). We identified the protein kinase C delta (PKCδ) inhibitor rottlerin as the only compound that reduced NO-induced ARE-luciferase reporter activity and diminished NO-induced up-regulation of two Nrf2/ARE-regulated proteins - NAD(P)H:quinone oxidoreductase-1 (NQO1) and hemeoxygenase-1 (HO-1) in SH-Sy5y cells. Rottlerin also sensitized neuroblastoma cells and mouse primary cortical neurons to NO-induced apoptosis. Stable over-expression of PKCδ augmented NO-induced, ARE-dependent gene expression of HO-1 in SH-Sy5y cells, which were more protected from NO killing. Conversely, NO-induced ARE-dependent gene expression was reduced in PKCδ-knockdown SH-EP cells, which displayed greater sensitivity to apoptosis. PKCδ^−/− cortical neurons exhibited increased NO-induced apoptosis and less HO-1 mRNA and protein induction compared with wild type neurons. Hence, PKCδ is an important positive modulator of NO-induced Nrf2/ARE-dependent signaling that counteracts NO-mediated apoptosis in neuronal cells.     

Differential regulation of metallothionein-I and metallothionein-II mRNA expression in the rat brain following traumatic brain injury

In this study, we investigated the expression of metallothionein (MT)-I and MT-II in the rat brain following traumatic brain injury (TBI). In the early stage, significant induction of MT-I and MT-II were observed in various regions including ventricle walls, pia mater, and dentate gyrus. At 12-24 h after TBI, strong induction of MT-I mRNA was observed in cerebral cortical layer II/III, amygdala, and piriform cortex where neurons reside. On the other hand, MT-II appeared to be expressed mainly in glial cells localized in the cerebral cortex and hippocampal formation. Three days after TBI, MTs were observed in the vimentin-positive astrocytes in the penumbra as revealed by double immunohistochemistry. The differences in expression of MT-I and MT-II in different brain regions and cell types (neuron vs. glial cells) suggests that multiple regulatory mechanisms are involved in the control of MT expression following brain injury.     

Activation of the complete mouse metallothionein gene locus in the maternal deciduum

The mouse metallothionein (MT) gene family consists of four known members (MT-I through IV) clustered on chromosome 8. Studies reported herein examine the expression and regulation of the MT-III and MT-IV genes in specific cell types in the maternal reproductive tract, developing embryo, and fetus known to express the MT-I and -II genes. MT-III and MT-IV mRNAs were absent from the visceral yolk sac, placenta, and fetal liver, tissues with high levels of MT-I and MT-II mRNAs. In contrast, MT-III and MT-IV mRNAs were both abundant in the maternal deciduum, and in experimentally induced deciduoma on 7 and 8 days postcoitum (1 dpc = vaginal plug), as are MT-I and -II mRNAs. The abundance of each of these MT mRNAs increased coordinately during development of the deciduum (6–8 dpc), and in situ hybridization localized MT-I, MT-III, and MT-IV mRNAs to the secondary decidual zone of the antimesometrial region on 8 dpc, where in some regions all of the cells were apparently positive. Thus, all of the known mouse MT genes are co-expressed in at least some of the cells in the secondary decidual zone. Electrophoretic analysis of decidual MT suggested that the MT-I, -II, and -III isoforms are abundant proteins in the secondary deciduum. Bacterial endotoxin-lipopolysaccharide (LPS) and Zn are powerful inducers of MT-I and MT-II gene expression in many adult organs, whereas these agents apparently have little effect on MT-III and MT-IV gene expression. Neither of these agents significantly effected levels of decidual MT-III or MT-IV mRNAs in vivo or in primary cultures of decidual cells in vitro, and only modest effects of Zn on MT-I mRNA levels were noted. During 2 days of in vitro culture, decidual cell MT-I and MT-III mRNA levels remained elevated while MT-IV mRNA levels decreased. Thus, expression of the mouse MT gene locus in the deciduum appears to be developmentally regulated, and in this tissue, the MT genes are refractory to induction by Zn or inflammation. © 1996 Wiley-Liss, Inc.     

Distal regulatory elements from the mouse metallothionein locus stimulate gene expression in transgenic mice.

DNA regions of 10 and 7 kb that flank the mouse metallothionein II (MT-II) and MT-I genes, respectively, were combined with a minimally marked MT-I (MT-I*) gene and tested in transgenic mice. This construct resulted in (i) position-independent expression of MT-I* mRNA and copy number-dependent expression, (ii) levels of hepatic MT-I mRNA per cell per transgene that were about half that derived from endogenous MT-I genes, (iii) appropriate regulation by metals and hormones, and (iv) tissue distribution of transgene mRNA that resembled that of endogenous MT-I mRNA. These features were not observed when MT-I* was tested without the flanking regions. These MT-I flanking sequences also improved the expression of rat growth hormone reporter genes, with or without introns, that were under the control of the MT-I promoter. Moreover, they enhanced expression from two of four heterologous promoters/enhancers that were tested. Deletion analysis indicated that regions known to have DNase I-hypersensitive sites were necessary but not sufficient for high-level expression. These data suggest that the DNA regions flanking the mouse MT-I and MT-II genes have functions like the locus control regions described for other genes.     

Different types of hypersensitive sites in the mouse metallothionein gene region

We have examined the chromatin structure of the metallothionein (MT) gene region in MT- S49 mouse lymphoma cells and in derivatives which express MT-I alone, MT-II alone, or both genes. In all lines, these genes are contained in a 16-kilobase pair region between two DNase I sensitive sites: one site located 5.3 kilobase pairs 5' of MT-II (the 5' gene) is present in naked DNA and retained in the chromatin of all lines; the other site located 3.1 kilobase pairs 3' of MT-I is hypersensitive. Hypersensitivity at three other sites is dependent on the expression of MT genes. Two sites 5' of MT-II disappear, and a site 3' of MT-I appears regardless of which gene is activated. The fact that these sites respond when either gene is activated suggests that the regulation of the two genes is interdependent and that the region undergoes a general change in conformation with MT activation. In addition, a single site in the 5' region of MT-II becomes hypersensitive with activation of the gene and may be related directly to expression.     

Selective and tandem amplification of a member of the metallothionein gene family in Candida glabrata

Metallothioneins constitute a multigene family in the yeast Candida glabrata. Two genes, designated metallothionein-I (MT-I) and one member of the metallothionein-II family (MT-II), were cloned and sequenced previously (Mehra, R. K., Garey, J. R., Butt, T. R., Gray, W. R., and Winge, D. R. (1989) J. Biol. Chem. 264, 19747-19753). Southern analysis of the genomic DNA samples from different wild-type isolates indicated that the MT-I gene was always present as a single copy but multiple (3-9) and tandemly arranged copies of one MT-II gene were present in different strains. Strains of C. glabrata highly resistant to copper salts were obtained by repeated culturing of wild-type isolates in medium containing increasing concentrations of copper sulfate. These strains showed further stable chromosomal amplification (greater than 30 copies) of the MT-II gene. The MT-I gene remained as a single copy. Amplified copies of the MT-II gene were always arranged tandemly. One of the copper-resistant strains acquired more copies of the MT-II gene by apparent duplication of the chromosome carrying this gene. The size of the amplification unit was 1.25 kilobases. The principal MT-I and -II genes of C. glabrata were shown to map to different chromosomes by electrophoretic karyotypic analysis. The length of chromosome carrying MT-II gene increased appreciably in strains exhibiting the highest amplification of this gene. Northern analysis showed increased basal levels of MT-II mRNA in strains having highly amplified MT-II locus.     

Separation and quantitation of metallothioneins by high-performance liquid chromatography coupled with atomic absorption spectrophotometry

A rapid, reproducible, and sensitive high-performance liquid chromatography (HPLC) method for the determination of the concentrations of metallothionein-I (MT-I) and metallothionein-II (MT-II) in rat liver has been developed. Metallothioneins (MTs) were separated and quantitated by anion-exchange high-performance liquid chromatography coupled with atomic absorption spectrophotometry (AAS). Purified rat liver MT-I and MT-II, used as standards for developing the method, were easily resolved, eluting at 7.5 and 10.4 min, respectively. To establish standard curves, protein concentrations of solutions of the purified MTs were determined by the Kjeldahl method for the determination of nitrogen, after which the standards were saturated with Cd (final concentration of 50 ppm Cd). Rat liver cytosols obtained from untreated and Cd- or Zn-treated rats were prepared for HPLC-AAS analysis by saturation with Cd (50 ppm Cd) followed by heat denaturation (placing in a boiling water bath for 1 min). Based on the method of standard additions, recovery of MTs exceeded 95% and repeated injection of a sample yielded a coefficient of variance of approximately 2%. A detection limit of 5 micrograms MT/g liver was established for the method. Only MT-II was detected in untreated rats, whereas following exposure to Cd or Zn, both forms of MTs were detected. Concentrations of total MTs in liver of untreated and Cd- or Zn-treated rats were also determined by the Cd/hemoglobin radioassay (which fails to distinguish MT-I from MT-II) and indicated that results obtained with the HPLC-AAS method compared favorably to the Cd/hemoglobin radioassay. Thus, the HPLC-AAS method for quantitating MT-I and MT-II offers the advantage of determining the concentrations of both proteins in tissues and should be useful for studying the regulation of MT-I and MT-II.     

Metallothionein gene regulation in the preimplantation rabbit blastocyst

Expression of metallothionein (MT) genes in the preimplantation rabbit blastocyst was analysed by determination of the levels of MT mRNA and relative rates of MT synthesis. MT was found to be constitutively expressed at low levels in the blastocyst. Exposure of the day-6 blastocyst to zinc ions in vitro rapidly increased the level of MT gene expression in a dose-dependent manner, with a ten-fold induction in the relative rate of synthesis at 400 microM-Zn2+. Ion-exchange chromatography of pulse-labelled blastocyst protein showed that the relative rates of synthesis of both MT-I and MT-II were markedly increased following zinc treatment, with MT-I being the predominant isometallothionein. Zinc induction of MT synthesis in the blastocyst was also detected on day 4 of gestation just after the morula-to-blastocyst transition. In contrast to the zinc effects on MT, in vitro exposure to 10 microM-Cd2+ resulted in a large induction of MT mRNA but only a modest increase in the relative rate of MT synthesis. Cadmium was found to be toxic to the day-6 blastocyst, and 10 microM-Cd2+ induced an acute stress response as indicated by a dramatic induction of heat-shock protein (HSP-70) gene expression.     

Cadmium-induced elevation of hepatic isometallothionein concentrations in inbred strains of mice

Susceptibility to Cd toxicity differs among inbred strains of mice. For example, C3H/He mice are sensitive to Cd-induced hepatotoxicity while DBA/2 mice are resistant. Metallothionein (MT), which in rodents exists predominantly as two isoproteins (MT-I and MT-II), is an important endogenous protein in the detoxication of Cd. The present investigation examines the possibility that strain-dependent susceptibility to Cd-induced liver injury is mediated by an inherited inability to accumulate a specific isoform of MT in response to Cd exposure. Hepatic concentrations of MT-I and MT-II were measured in C3H/He (Cd-sensitive) and DBA/2 (Cd-resistant) mice at various times after the administration of non-toxic (2.5 mumol Cd/kg) to hepatototoxic (80 mumol Cd/kg) dosages of Cd. The concentration of MT-I and MT-II in these strains was similar 24 h after injection of non-hepatotoxic dosages of Cd (10 mumol Cd/kg or less) as well as 6-12 h after a mildly hepatotoxic dose of Cd (20 mumol Cd/kg). The concentration of total MT in liver of Cd-sensitive mice was greater than that present in resistant mice 24-72 h after 20 mumol Cd/kg injection. The data indicates that susceptibility to Cd-induced hepatotoxicity observed in C3H/He mice is not due to a deficit in the induction of a particular isoform of MT.