Metallothionein Mto gene of Drosophila melanogaster: structure and regulation

Genetics of metallothioneins in Drosophilamelanogaster

Metallothioneins (MTs) are ubiquitous metal-chelating proteins involved in cellular metal homeostasis. MTs were found to be related with almost all the biological processes and their malfunctioning is responsible for a lot of important human diseases. Invertebrate MTs were also used broadly as biomarkers of metal contamination due to their inducible expression by metal exposure. MT system plays a significant role in maintaining human health and ecological stability. Drosophila melanogaster, the vinegar fly, is a perfect model for studying insect MT systems. Six MTs were identified in D. melanogaster, and were designated MtnA to F. All the MTs are considered as Cu-thioneins except for MtnF, which is putatively a Zn-thionein. Expression of all the MTs are regulated by MTF-1/MRE system, thus being able to be induced by heavy metal exposure. The expression pattern and function of separated MTs are partially overlapped and partially distinct. In this work, we made a summary of all the studies on D. melanogaster MTs. From this review, we noted that, compared with studies on mammalian MTs, the understanding of the MT system of D. melanogaster and other invertebrates, especially the regulation mechanism for MT expression and protein-protein interaction with them, is still in a low level.

Gawky modulates MTF-1-mediated transcription activation and metal discrimination

Metal-induced genes are usually transcribed at relatively low levels under normal conditions and are rapidly activated by heavy metal stress. Many of these genes respond preferentially to specific metal-stressed conditions. However, the mechanism by which the general transcription machinery discriminates metal stress from normal conditions and the regulation of MTF-1-meditated metal discrimination are poorly characterized. Using a focused RNAi screening in Drosophila Schneider 2 (S2) cells, we identified a novel activator, the Drosophila gawky, of metal-responsive genes. Depletion of gawky has almost no effect on the basal transcription of the metallothionein (MT) genes, but impairs the metal-induced transcription by inducing the dissociation of MTF-1 from the MT promoters and the deficient nuclear import of MTF-1 under metal-stressed conditions. This suggests that gawky serves as a 'checkpoint' for metal stress and metal-induced transcription. In fact, regular mRNAs are converted into gawky-controlled transcripts if expressed under the control of a metal-responsive promoter, suggesting that whether transcription undergoes gawky-mediated regulation is encrypted therein. Additionally, lack of gawky eliminates the DNA binding bias of MTF-1 and the transcription preference of metal-specific genes. This suggests a combinatorial control of metal discrimination by gawky, MTF-1, and MTF-1 binding sites.

Chronic lead (Pb) exposure results in diminished hemocyte count and increased susceptibility to bacterial infection in Drosophila melanogaster

Heavy metal Pb is a common toxic pollutant present in our environment adversely affecting health of the living organisms. Recent studies suggest positive correlation between heavy metal exposure and immune dysfunction and present work utilizes Drosophila to address this issue in relation to Pb exposure. In-vivo Pb toxicity was established by dietary intake where essential parameters like development and life span were found to be hampered and augmented upon metallothionein B (mtnB) downregulation hinting towards potential role of mtnB in Pb detoxification. Further response of Drosophila to B. subtilis bacterial infection was monitored by carrying out oral infections. Pb fed flies showed increased susceptibility to infection as compared to their controls. Since Drosophila hemocytes play dual role as immune cells, we checked for the total hemocyte count and found significant decrease in hemocyte numbers in Pb fed larvae. Both crystal cells and plasmatocytes, the two major hemocytes in third instar larval hemolymph were reduced. However we did not find any visible morphological changes in Giemsa stained hemocytes. Crystal cells are crucial for synthesis and release of phenoloxidase (PO), an enzyme required for melanin clot synthesis and deposition. PO activity assessed from total hemolymph protein isolates was found to be substantially decreased in Pb raised animals. Results were also confirmed by spot test and native gel activity assay of PO. Overall our results suggest immunotoxic effect of Pb through decrease in hemocyte count including crystal cell which in turn leads to decreased PO activity and increased susceptibility to B. subtilis.

Metallothioneins of the urochordate Oikopleura dioica have Cys-rich tandem repeats, large size and cadmium-binding preference

Oikopleura dioica has the longest metallothionein described so far, made of repeats generated by a modular and step-wise evolution.

GENETIC BASIS OF A BETWEEN-ENVIRONMENT TRADE-OFF INVOLVING RESISTANCE TO CADMIUM IN DROSOPHILA MELANOGASTER

In a replicated, laboratory, natural selection experiment Drosophila melanogaster populations were maintained for 20 generations either on unpolluted medium or on polluted medium containing cadmium chloride at a concentration of 80 μg/ml. Lines maintained on polluted medium evolved resistance. In comparison with unpolluted lines, their juvenile survivorship increased from 35% to 46%, developmental period decreased from 13.7 days to 13.0 days, and fecundity increased from 3 to 29 eggs per two-day period. Emergence weights, however, did not change. By contrast the "environmental" effect of moving susceptible flies onto polluted medium was that after two generations survivorship fell 62%, developmental period increased 40%, and fecundity fell 97%. Emergence weights fell 31% in females and 28% in males. Resistant lines paid a fitness cost in unpolluted environments, with fecundity being reduced by 44% and emergence weights being reduced by 4% in females and 6% in males. Developmental period, however, was unaffected. Analyses of crosses and backcrosses between the lines suggested that the evolved cadmium resistance was due to a single sex-linked gene. Levels of dominance were calculated, and in each life-history character the resistant allele was found to be completely dominant. Because the life-history effects appear to be produced by a single gene, it is probable that they all depend on the same metabolic pathway. Metallothionein production is a likely candidate because this is known to be controlled by genes on the X-chromosome. The study adds to a small number of examples of single or closely linked genes with large antagonistic pleiotropic effects on life histories. The result here is a between-environment trade-off, allowing animals increased fitness in polluted environments, but only at the cost of reduced growth and reproduction in unpolluted environments.

Efficient metal-specific transcription activation by Drosophila MTF-1 requires conserved cysteine residues in the carboxy-terminal domain

MTF-1 is a sequence-specific DNA binding protein that activates the transcription of metal responsive genes. The extent of activation is dependent on the nature of the metal challenge. Here we identify separate regions within the Drosophila MTF-1 (dMTF-1) protein that are required for efficient copper- versus cadmium-induced transcription. dMTF-1 contains a number of potential metal binding regions that might allow metal discrimination including a DNA binding domain containing six zinc fingers and a highly conserved cysteine-rich C-terminus. We find that four of the zinc fingers in the DNA binding domain are essential for function but the DNA binding domain does not contribute to the metal discrimination by dMTF-1. We find that the conserved C-terminus of the cysteine-rich domain provides cadmium specificity while copper specificity maps to the previously described copper-binding region (Chen et al.). In addition, both metal specific domains are autorepressive in the absence of metal and contribute to the low level of basal transcription from metal inducible promoters.

The parkin mutant phenotype in the fly is largely rescued by metal-responsive transcription factor (MTF-1)

The gene for Parkin, an E3 ubiquitin ligase, is mutated in some familial forms of Parkinson's disease, a severe neurodegenerative disorder. A homozygous mutant of the Drosophila ortholog of human parkin is viable but results in severe motoric impairment including an inability to fly, female and male sterility, and a decreased life span. We show here that a double mutant of the genes for Parkin and the metal-responsive transcription factor 1 (MTF-1) is not viable. MTF-1, which is conserved from insects to mammals, is a key regulator of heavy metal homeostasis and detoxification and plays additional roles in other stress conditions, notably oxidative stress. In contrast to the synthetic lethality of the double mutant, elevated expression of MTF-1 dramatically ameliorates the parkin mutant phenotype, as evidenced by a prolonged life span, motoric improvement including short flight episodes, and female fertility. At the cellular level, muscle and mitochondrial structures are substantially improved. A beneficial effect is also seen with a transgene encoding human MTF-1. We propose that Parkin and MTF-1 provide complementary functions in metal homeostasis, oxidative stress and other cellular stress responses. Our findings also raise the possibility that MTF-1 gene polymorphisms in humans could affect the severity of Parkinson's disease.

Metallothioneins in Diptera

Dipterean insecta owe their relevance to the well-known model organism D. melanogaster, and extensively to the Drosophila genus. In the frame of the study of metallothioneins (MTs), they constitute a bizarre exception, since Drosophila is the only metazoan organism synthesizing only MTs similar to the yeast (S. cerevisiae) Cup1 paradigmatic copper-thionein. D. melanogaster MTs are optimized for copper binding and metabolism, and no MT analogous to the mammalian MTs has been identified, unlike in the cases of other Arthropoda and invertebrates analyzed so far (Chapters 7 and 8 of this book). The D. melanogaster genome contains four MT genes (MtnA, MtnB, MtnC, and MtnD), which are clustered in the same genomic region, probably arising from amplifying duplications. The main isoforms are MtnA and MtnB, encoding peptides 40- and 43-amino acids long, comprising 10 and 12 cysteines, respectively. MtnC and MtnD probably arise from recent MtnB duplications and play a minor role in flies. Expression of the four genes is dependent on dMTF-1, a transcriptional activator homologous to the mammalian MTF-1. Major MT synthesis in larvae and adults is observed in the digestive tract, mainly in the midgut, although with a different distribution between MtnA and MtnB. Other tissues of Mtn gene expression are salivary glands, ventricula, Malpighian tubules, and hemocytes. Metal induction increases the rate of MT synthesis in these tissues, but not normally in MT gene-silent organs, and invariably, the best response is obtained for copper, followed by cadmium, and very poorly for zinc. In conclusion, all the available data suggests a definitive role of D. melanogaster MT in copper metabolism (from ingestion to distribution, storage, delivery, and detoxification in the organism) as well as in cadmium tolerance (by digestive assimilation blockage). This is readily confirmed by studies of population genetics that show that both spontaneous MtnA genomic duplications, independently isolated in worldwide locations, and fly strains containing supernumerary Mtn genes constructed in the laboratory are able to tolerate increased copper and cadmium concentrations; while Mtn and dMTF-1 knock-outs are extremely sensitive to these conditions.

Assessment of heavy metals concentrations in soil samples from the vicinity of busy roads: influence on Drosophila melanogaster life cycle

An assessment of Cd, Cu, Pb, and Zn in 25 soil samples collected near busy roads in Irbid city, Jordan indicated contamination of these soil samples with different concentrations of 624, 1.243, 242, and 847 microg/g for Pb, Cd, Cu, and Zn, respectively. The survival percentage of Drosophila melanogaster third-instar larvae on synthetic medium containing these concentrations for the first generation shows a significant reduction in their growth and development or metamorphosis for most soil extracts. Moreover, there was a significant reduction in survival growth and development in the second generation. The survival percentages of the second generation at pupa stage was higher than the first generation, whereas at the adult stage, there was a lower survival percentage indicating some effects on metamorphosis caused by concentration of heavy metals on Drosophila melanogaster.

Identification, cloning and sequencing of a novel stress inducible metallothionein gene from locally isolated Tetrahymena tropicalis lahorensis

A novel cadmium inducible metallothionein (TMCd1) gene has been identified and sequenced from the locally isolated ciliate, Tetrahymena tropicalis lahorensis from industrial effluents. The TMCd1 gene encodes 471 nucleotides, with TGA as the stop codon and TAA coding for glutamine. This new gene is quite different from the previously reported MT genes in Tetrahymena pyriformis and Tetrahymena pigmentosa. However, it shows 78% homology with four different Cd-MT genes reported from Tetrahymena thermophila. A TATA box is located in the 5' flanking region at nucleotide 34-38 upstream region of ATG. The TMCd1 gene is intronless like many other genes isolated from Tetrahymena species. The amino acids sequence of TMCd1 has a special feature of three CCCX(6)CCX(6)CCCX(6)CC and two CCX(6)CXCX(2)CXCC intragenic tandem repeats with a conserved structural pattern of cysteine. The translated protein of TMCd1 contains 30.12% cysteine residues, which is a characteristic of a typical Tetrahymena Cd inducible MT genes. On the basis of 78% homology of nucleotide sequence of genomic DNA and its cDNA, TMCd1 has been considered as a new gene being reported from Tetrahymena tropicalis from this part of the world.

Copper homeostasis gene discovery in Drosophila melanogaster

Recent studies have shown a high level of conservation between Drosophila melanogaster and mammalian copper homeostasis mechanisms. These studies have also demonstrated the efficiency with which this species can be used to characterize novel genes, at both the cellular and whole organism level. As a versatile and inexpensive model organism, Drosophila is also particularly useful for gene discovery applications and thus has the potential to be extremely useful in identifying novel copper homeostasis genes and putative disease genes. In order to assess the suitability of Drosophila for this purpose, three screening approaches have been investigated. These include an analysis of the global transcriptional response to copper in both adult flies and an embryonic cell line using DNA microarray analysis. Two mutagenesis-based screens were also utilized. Several candidate copper homeostasis genes have been identified through this work. In addition, the results of each screen were carefully analyzed to identify any factors influencing efficiency and sensitivity. These are discussed here with the aim of maximizing the efficiency of future screens and the most suitable approaches are outlined. Building on this information, there is great potential for the further use of Drosophila for copper homeostasis gene discovery.

Regulation of metallothionein genes in the American oyster (Crassostrea virginica): Ontogeny and differential expression in response to different stressors

Metallothioneins (MTs) are typically low molecular weight (6-7 kDa), metal-binding proteins with characteristic repeating cysteine motifs (Cys-X-Cys or Cys-Xn-Cys) and a prolate ellipsoid shape containing single alpha- and beta-domains. While functionally diverse, they play important roles in metals homeostasis, detoxification and the stress response. The present study, combined with previous observations (e.g., Jenny et al., Eur. J. Biochem. 2005; 271:1702-1712) defines an unprecedented diversity of MT primary structure and domain organization in the American oyster, Crassostrea virginica. Two novel molluscan MT families are described. One of these (CvMT-III) is characterized by the presence of two beta-domains and the absence of alpha-domains. This family exhibits constitutive expression during larval development and is the dominant CvMT isoform expressed in larvae. CvMT-III displays low basal levels of expression in adult tissues and only moderate responsiveness to metal challenges in both larvae and adults. A second novel MT isoform (CvMT-IV) was isolated from hemocytes by subtractive hybridization techniques following a 4-hour immune challenge with heat-killed bacteria (Vibrio, Bacillus, Micrococcus spp. mixture). Based on conservation of the cysteine motifs, this isoform appears to be a sub-family related to the molluscan alphabeta-domain MTs. A series of amino acid substitutions has resulted in four additional cysteines which give rise to a Cys-Cys motif and three Cys-Cys-Cys motifs. Northern blot analyses demonstrate that CvMT-IV is down-regulated upon sterile wounding and immune challenge, displays moderate expression in larvae and adults and differential gene induction in response to metals exposure.

Copper homeostasis in eukaryotes: Teetering on a tightrope

The transition metal copper is an essential trace element for both prokaryotes and eukaryotes. However, intracellular free copper has to be strictly limited due to its toxic side effects, not least the generation of reactive oxygen species (ROS) via redox cycling. Thus, all organisms have sophisticated copper homeostasis mechanisms that regulate uptake, distribution, sequestration and export of copper. From insects to mammals, metal-responsive transcription factor (MTF-1), a zinc finger transcription factor, controls expression of metallothioneins and other components involved in heavy metal homeostasis. In the fruit fly Drosophila, MTF-1 paradoxically acts as an activator under both high and low copper concentrations. Namely, under high copper conditions, MTF-1 activates metallothioneins in order to protect the cell, while under low copper conditions MTF-1 activates the copper importer Ctr1B in order to acquire scarce copper from the surroundings. This review highlights the current knowledge of copper homeostasis in eukaryotes with a focus on Drosophila and the role of MTF-1.

The effect of different concentrations of lead on inversion polymorphism in Drosophilasubobscura

Drosophila subobscura is a wild Drosophila species that is spread over almost all of Europe. It possesses an uniquely rich inversion polymorphism on all five long chromosomes. This polymorphism is to a certain degree associated with the variation and dynamics of ecological factors in space and time. We analyzed the changes of inversion polymorphism components of Drosophila subobscura flies maintained on media with different concentrations of lead in laboratory conditions. The effects of lead on inversion polymorphism were observed by cytological analysis of gene arrangements on all of the five acrocentric chromosomes, as well as by cytological analysis of karyotypes on all of the four autosomes. The frequencies of particular gene arrangements on the four autosomes changed significantly in the samples maintained on medium not supplemented with lead. The frequencies of some gene arrangements on all of the five acrocentric chromosomes changed significantly in the flies maintained on media supplemented with lead. The length of exposure to different lead concentrations results in a significant change in the frequency of a few gene arrangements on two autosomes. However, the results show that different concentrations of lead, as well as the length of exposure, do not affect major parameters of inversion polymorphism. The results suggest that some gene arrangements could be linked with adaptive processes in evolving heavy metal resistance.

Effects of heavy metals on population growth and metallothionein gene expression in the mosquito Culex quinquefasciatus, from Calcutta, India

Major water bodies in and around the city of Calcutta (India) receive heavy metal contaminated effluents from industries, households, and vehicular traffic through sewage or drainage. We quantified concentrations of Cu, Zn, and Cd from three water bodies at Kalighat, Tangra, and VIP Road, respectively. The concentrations of these heavy metals were significantly greater in the summer than in monsoon when heavy downpours resulted in reduced metal concentrations. Concentrations of metals in the mosquito Culex quinquefasciatus also reflected such seasonal fluctuations. Hatchability and survivorship of C. quinquefasciatus significantly differed among the sites and were reduced significantly from the control. Exposure to heavy metals also induced MT-gene expression in C. quinquefasciatus, likely helping them to survive in the water bodies stressed with heavy metals. MT-gene activity demonstrated significant variation among sites and seasons with the highest activity in the summer in the VIP Road population. This study suggests that C. quinquefasciatus could be used as an ecological indicator of heavy metal pollution by monitoring its MT-gene expression.

MTO: the second member of a Drosophila dual copper-thionein system

Drosophila MTO metal binding features were analyzed for comparison with MTN, the paralogous Drosophila metallothionein, and to classify MTO as either zinc- or copper-thionein. This was achieved by a combination of in vivo, in vitro and in silico methodologies. All the results unambiguously classified MTO as a second Drosophila copper-thionein, putting Drosophila forward as the only metazoan in which any zinc-thionein has still to be reported. Interestingly, experimental data only showed minor differences in the coordinative behavior of both MTs, but provided a characteristic spectroscopic fingerprint, revealing the possible binding of chloride anions in certain metal-MTO aggregates.

Cloning of a metallothionein gene and characterization of two other cDNA sequences in the Pacific oyster Crassostrea gigas (CgMT1)

Metallothionein (MT) genes encode essential metal-binding proteins involved in metallic homeostasis and detoxification in living organisms. Here, we describe the structure of the first Pacific oyster Crassostrea gigas metallothionein (CgMT1) gene and the sequences of two other MT cDNA. The CgMT1 gene sequence contains three coding exons plus a 5' entirely non-coding exon, and the predicted protein contains 21 cysteine residues organized in Cys-X-Cys motifs as classically described for MTs. The three cDNA sequences present few substitutions in either coding sequence or UTRs. Induction of these MT-mRNA in heavy metal-treated oysters (i.e. cadmium) was confirmed by Northern blot analysis and RT-PCR and suggests a potential specific tissue expression rate. Southern blot analysis suggested the presence of multiple CgMT genes, and allowed the detection of restriction fragment length polymorphisms (RFLPs). Although the CgMT1 coding sequence showed 30-73% nucleotide identities with known sequences in other mollusks, it included the specific motif Cys-X-Cys-X(3)-Cys-Thr-Gly-X-X-X-Cys-X-Cys-X(5)-Cys-X-Cys-Lys found in Mollusk family 2. Marine bivalves are commonly used as pollution bioindicators, thus the development of genetic markers based on CgMT1 polymorphism will allow a monitoring of heavy metal exposure in anthropogenically disturbed ecosystems.

The Drosophila homolog of mammalian zinc finger factor MTF-1 activates transcription in response to heavy metals

Metallothioneins (MTs) are short, cysteine-rich proteins for heavy metal homeostasis and detoxification; they bind a variety of heavy metals and also act as radical scavengers. Transcription of mammalian MT genes is activated by heavy metal load via the metal-responsive transcription factor 1 (MTF-1), an essential zinc finger protein whose elimination in mice leads to embryonic lethality due to liver decay. Here we characterize the Drosophila homolog of vertebrate MTF-1 (dMTF-1), a 791-amino-acid protein which is most similar to its mammalian counterpart in the DNA-binding zinc finger region. Like mammalian MTF-1, dMTF-1 binds to conserved metal-responsive promoter elements (MREs) and requires zinc for DNA binding, yet some aspects of heavy metal regulation have also been subject to divergent evolution between Drosophila and mammals. dMTF-1, unlike mammalian MTF-1, is resistant to low pH (6 to 6.5). Furthermore, mammalian MT genes are activated best by zinc and cadmium, whereas in Drosophila cells, cadmium and copper are more potent inducers than zinc. The latter species difference is most likely due to aspects of heavy metal metabolism other than MTF-1, since in transfected mammalian cells, dMTF-1 responds to zinc like mammalian MTF-1. Heavy metal induction of both Drosophila MTs is abolished by double-stranded RNA interference: small amounts of cotransfected double-stranded RNA of dMTF-1 but not of unrelated control RNA inhibit the response to both the endogenous dMTF-1 and transfected dMTF-1. These data underline an important role for dMTF-1 in MT gene regulation and thus heavy metal homeostasis.

Regulation of metallothionein gene expression

The rapid and robust induction of metallothioneins (MT)-I and II by a variety of inducers that include heavy toxic metals, reactive oxygen species, and different types of stress provide a useful system to study the molecular mechanisms of this unique induction process. The specific expression of MT-III in the brain and of MT-IV in the squamous epithelium of skin and tongue offers a unique opportunity to identify and characterize the tissue-specific factors involved in their expression. Studies using transgenic mice that overexpress MTs or MT null mice have revealed the role of MT in the protection of cells against numerous tissue-damaging agents such as reactive oxygen species. The primary physiological function of these proteins, however, remains an enigma. Considerable advances have been made in the identification of the cis-acting elements that are involved in the constitutive and induced expression of MT-I and MT-II. By contrast, only one key trans-activating factor, namely MTF-1, has been extensively characterized. Studies on the epigenetic silencing of MT-I and MT-II by promoter hypermethylation in some cancer cells have posed interesting questions concerning the functional relevance of MT gene silencing, the molecular mechanisms of MT suppression in these cells, particularly chromatin modifications, and the characteristics of the repressors.

Drosophila MTN: a metazoan copper-thionein related to fungal forms

Two Drosophila metallothioneins (MT) have been reported: MTN, a 40 residue peptide including 10 Cys, and MTO, a 43 residue peptide including 12 Cys. However, neither functional nor evolutionary analyses for either of the Drosophila MT are available. Here, heterologous expression of Mtn in Escherichia coli is reported. The metal binding abilities of the Cu- and Zn-MTN complexes conformed in vivo, as well as the features of the Cd- and Cu-aggregates produced by metal replacement in vitro, have been determined by atomic emission spectrometry, circular dichroism and electrospray ionization mass spectrometry. Primary structure relationships with other MT have been examined. The results indicate a close resemblance of MTN to fungal copper-thioneins.

Regulation of metallothionein gene transcription. Identification of upstream regulatory elements and transcription factors responsible for cell-specific expression of the metallothionein genes from Caenorhabditis elegans

Metallothioneins are small, cysteine-rich proteins that function in metal detoxification and homeostasis. Metallothionein transcription is controlled by cell-specific factors, as well as developmentally modulated and metal-responsive pathways. By using the nematode Caenorhabditis elegans as a model system, the mechanism that controls cell-specific metallothionein transcription in vivo was investigated. The inducible expression of the C. elegans metallothionein genes, mtl-1 and mtl-2, occurs exclusively in intestinal cells. Sequence comparisons of these genes with other C. elegans intestinal cell-specific genes identified multiple repeats of GATA transcription factor-binding sites (i.e. GATA elements). In vivo deletion and site-directed mutation analyses confirm that one GATA element in mtl-1 and two in mtl-2 are required for transcription. Electrophoretic mobility shift assays show that the C. elegans GATA transcription factor ELT-2 specifically binds to these elements. Ectopic expression of ELT-2 in non-intestinal cells of C. elegans activates mtl-2 transcription in these cells. Likewise, mtl-2 is not expressed in nematodes in which elt-2 has been disrupted. These results indicate that cell-specific transcription of the C. elegans metallothionein genes is regulated by the binding of ELT-2 to GATA elements in these promoters. Furthermore, a model is proposed where ELT-2 constitutively activates metallothionein expression; however, a second metal-responsive factor prevents transcription in the absence of metals.

Metallothionein cDNA, promoter, and genomic sequences of the tropical green mussel, Perna viridis

The primary structure of the cDNA and metallothionein (MT) genomic sequences of the tropical green mussel (Perna viridis) was determined. The complete cDNA sequences were obtained using degenerate primers designed from known metallothionein consensus amino acid sequences from the temperate species Mytilus edulis. The amino acid sequences of P. viridis metallothionein deduced from the coding region consisted of 72 amino acids with 21 cysteine residues and 9 Cys-X-Cys motifs corresponding to Type I MT class of other species. Two different genomic sequences coding for the same mRNA were obtained. Each putative gene contained a unique 5'UTR and two unique introns located at the same splice sites. The promoters for both genes were different in length and both contained metal responsive elements and active protein-binding sites. The structures of the genomic clones were compared with those of other species. J. Exp. Zool. 284:445-453, 1999.

Cadmium metallothionein gene of Tetrahymena pyriformis

A genomic sequence from Tetrahymena pyriformis, encoding a cadmium-induced metallothionein has been cloned. The gene encodes a transcript of 487 bases, with an intronless coding region of 324 nt, using TGA as the stop codon, TAA coding for glutamine, and the translational initiation sequence AAAATGG. Two regions of internal similarity in the coding sequence support the hypothesis that the Tetrahymena protein arose by gene duplication. The sequences of untranslated regions show some similarities with nematode MT-1 and MT-2 transcripts. Sequence of 525 bases upstream of the transcription start contains a TATA box, a CAAT box reverse complement, and many short stretches partially matching the AP-1 and ACE-1 binding sites, but no characteristic sequences found in other metallothionein promoters.

Primary structure of a cadmium-induced metallothionein from the insect Orchesella cincta (Collembola)

The induction of metallothionein was studied in the springtail Orchesella cincta (Collembola), a species of insect living in forest soils. Upon dietary exposure to Cd, two Cd-binding, cysteine-rich peptides were isolated from whole-body homogenates, using gel filtration and reversed-phase FPLC. Mass spectrometric analysis revealed that the molecular masses of these peptides were 2989 Da and 4139 Da, respectively. Amino acid sequencing of the 2989-Da peptide resulted in a sequence typical for a metallothionein. Sequencing of the 4139-Da protein was unsuccessful, probably due to N-terminal blockage. Using different PCR techniques (3' and 5' RACE) with (degenerate) primers based on the identified amino acid sequence of the 2989 Da peptide, a metallothionein cDNA was isolated. The sequence of this cDNA potentially codes for a protein of 77 amino acids. The 2989 Da peptide corresponds to the C-terminal part of this protein. The 4139-Da protein is probably encoded by the N-terminal part of this protein. These results suggest that the identified peptides are products of one gene, and that the primary gene product is subject to post-translational processing. The deduced amino acid sequence of the O. cincta metallothionein shows low sequence similarity with metallothioneins from Drosophila. The similarity between O. cincta MT and MTs of invertebrates is not higher than that between O. cincta and vertebrates.

Cloning of a complementary DNA encoding an Ambystoma mexicanum metallothionein, AmMT, and expression of the gene during early development

We have used a polymerase chain reaction strategy to isolate a metallothionein (MT) cDNA from the amphibian Ambystoma mexicanum (axolotl). This cDNA is 875-bp long and encodes a 60 amino acid protein, AmMT, typical for family 1 MTs. It contains 20 cysteine (Cys) residues that can be aligned with those of other vertebrate MTs. The overall structure of the protein is unique among vertebrates in having only two amino acid residues before the first Cys at the amino-terminal end. Northern analyses showed that AmMT is expressed throughout embryogenesis, giving rise to three mRNA species of 650, 750, and 1,600 nucleotides (nt). The 750 and 1,600 nt transcripts appear to result from differential use of polyadenylation signals, whereas the 650 nt RNA could arise from deadenylation of the 750-nt transcript. Both the 750- and 1,600-nt RNAs were presented in embryos before the mid-blastula transition (MBT). After the MBT, the 750-nt RNA was replaced by the 650-nt RNA which was gradually degraded to undetectable levels in post-neurulation embryos. Levels of the 1,600-nt transcript increased at gastrulation and reach a maximum in Stage 30 embryos. In adult animals, levels of the 750-nt RNA were high in liver and testes, and very low in lung, gut, skin, and oviducts, whereas levels of the 1,600-nt transcript were similar and moderately elevated in all tissues examined. In contrast, in Xenopus laevis, Northern analysis did not detect XIMT-A mRNA in embryos before late neurulation (Stage 24). XIMT-A mRNA levels then increased sharply in Stage 36 hatched embryos at levels similar to those found in adult livers. These results show that AmMT presents a unique expression pattern among metazoans being transcribed as two transcripts differing in the length of their 3' untranslated regions, the levels of which vary during embryogenesis and in adult tissues.

Response of Drosophila metallothionein promoters to metallic, heat shock and oxidative stresses

The metallothionein system in Drosophila melanogaster is composed of two genes, Mtn and Mto. In order to compare the induction properties of these genes, we transformed D. melanogaster with P-element vectors containing Adh and lacZ reporter genes under the control of Mtn and Mto promoters, respectively. Mtn and Mto transgenes are mainly expressed in digestive tract. However, Mtn expression has been detected also in the fat body. Mtn and Mto transgenes respond differently to metallic, heat-shock and oxidative stresses. These data confirm that both genes are in part functionally different.

Developmental variability of metallothionein Mtn gene expression in the species of the Drosophila melanogaster subgroup

Developmental expression of the Drosophila melanogaster metallothionein Mtn gene has been analysed. Transcripts of this gene accumulate during the vitellogenic phase of oogenesis in a ring of follicular cells at the oocyte-nurse cell margin and in the follicular cells surrounding the oocyte. There is also strong expression of the Mtn gene during the second half of embryogenesis in hemocytes, the endoderm midgut, and Malpighian tubules. A banded expression pattern is observed transiently in the midgut at stage 13. The two Mtn alleles, Mtn and Mtn, show quantitative differences in their expression patterns. Copper intoxication of flies does not induce ectopic expression of the Mtn gene, but rather leads to over-expression of the gene in the structures where it is normally transcribed. Mtn transcription is not altered in homozygous mutants of four genes (lab, wg, dpp, bap) known to be involved in midgut morphogenesis. Expression of Mtn has been also studied in six other species of the melanogaster subgroup. This analysis demonstrates that regulation of Mtn gene transcription has changed during evolution of the Drosophila lineage. For example, Mtn is expressed specifically in the Malpighian tubules of D. melanogaster, while in D. mauritiana and D. sechellia the amnioserosa is a specific location of expression. Nonetheless, expression of Mtn in the midgut is common to the seven species, suggesting a basic role for the MTN protein during embryogenesis in this organ, possibly in the release of metallic ions from vitellogenins. In contrast, two genes also expressed in the embryonic midgut, lab and dFRA, display identical patterns in all species of the melanogaster subgroup. The diversity of Mtn patterns in closely related Drosophila species exemplifies the rapid evolution of a gene regulatory system.

Purification and primary structure of metallothioneins induced by cadmium in the protists Tetrahymena pigmentosa and Tetrahymena pyriformis

Tetrahymena pyriformis and Tetrahymena pigmentosa grown in the presence of a non-toxic dose of cadmium, accumulate the metal in the cytosol. Purification by gel-permeation, ion-exchange and reverse-phase high-performance liquid chromatography showed that the metal is bound principally to newly formed proteins with ultraviolet spectra and cysteine contents similar to those of Cd(2+)-metallothioneins from multicellular organisms. The isolated proteins revealed that the two species of ciliates each express two Cd(2+)-isothioneins. The primary structures determined by both Edman degradation and mass spectrometry revealed that the equivalent proteins from T. pyriformis and T. pigmentosa have identical sequences and that the two isoforms in each species differ only by the presence or absence of a lysine residue at the N-terminus. The development of automated mass spectrometric sequence analysis algorithms combined with an accurate determination of the molecular mass allowed the rapid confirmation of the sequences. The Tetrahymena metallothionein sequences are unusually long (105 and 104 amino acids) and show a unique internal homology which suggests that the proteins arose by gene duplication. The chains contain 31 cysteine residues, 15 of which are arranged in motifs characteristic of the mammalian metallothioneins; the remaining residues show several unique repeating motifs, which could have interesting consequences for the tertiary structure of the metal-binding sites. Amino acid sequences of Tetrahymena metallothioneins have some similarity with other eukaryotic metallothioneins. A comparison on the basis of optimised FASTA scores, shows a closer relationship with horse metallothionein-1B.

Transcriptional induction of the mouse metallothionein-I gene in hydrogen peroxide-treated Hepa cells involves a composite major late transcription factor/antioxidant response element and metal response promoter elements

Synthesis of metallothionein-I (MT-I) and heme oxygenase mRNAs is rapidly and transiently induced by H2O2 in mouse hepatoma cells (Hepa) and this effect is blocked by catalase. Menadione, which generates free radicals, also induces these mRNAs. Deletion mutagenesis revealed that a region between -42 and -153 in the mouse MT-I promoter was essential for induction of a CAT reporter gene. A multimer of a 16 bp sequence (-101 to -86) that includes an antioxidant response element and overlapping adenovirus major late transcription factor binding site elevated basal expression and allowed induction by H2O2 when inserted upstream of a minimal promoter. However, deletion of this region (-100 to -89) from the intact MT-I promoter (-153) did not completely eliminate response. Multiple copies of a metal response element also permitted response to H2O2. These results suggest that induction of MT-I gene transcription by H2O2 is mediated by at least two different elements within the proximal MT-I gene promoter and suggest a previously undescribed function of the MRE. Induction of MT gene transcription by ROS and the subsequent scavenging of ROS by the MT peptide is reminiscent of the metal regulatory loop and is consistent with the hypothesized protective functions of MT.

Molecular cloning and expression of a metallothionein mRNA in Xenopus laevis

Metallothioneins (MT) are expressed during early development in species of several groups. To understand MT function in developmental processes, we studied the MT system of Xenopus laevis, a model vertebrate species in experimental embryology. We first purified and sequenced the liver MT from copper-treated animals. This 62-amino-acid protein shares the main structural properties of known vertebrate MT, and is more closely related to avian than to fish or mammalian MT. Using this sequence, we designed oligonucleotide primers to amplify and isolate a MT clone from a XL2 cell line cDNA library. This 752-bp cDNA encodes a putative 62-amino-acid-long protein that is 100% identical with the sequenced MT. Zinc, cadmium, and copper ions are very efficient inducers of MT mRNA accumulation in Xenopus liver and cell lines.

Recent evolutionary history of the metallothionein gene Mtn in Drosophila

A new allele of one of the metallothionein genes of D. melanogaster, Mtn.3, sheds light on the recent evolution of this gene. In comparison to the previously studied Mtn1 allele found in Canton S, this new allele, Mtn.3, produces a transcript that is 49 bases longer and 65-70% less abundant. We detected Mtn.3 in several laboratory strains as well as in isofemale lines derived from natural populations. Sequence comparison showed that Mtn.3 differs from Mtn1 in that it has: (a) base-pair substitution and an extra 49 bp-segment in the 3' untranslated region, (b) a substitution in the coding region that replaces the terminal Glu40 in Mtn1 with Lys40, and (c) two base-pair substitutions in the promoter region. The Mtn.3-type was detected in six species of the melanogaster group by restriction analysis, and this result was confirmed by sequencing the D. simulans Mtn gene. Thus Mtn.3, which produces a less abundant transcript, appears to be the oldest of the two alleles. We also found that the duplications previously isolated from natural populations all derived from Mtn1, the more recent allele. Thus, two evolutionary steps: Mtn.3 to Mtn1 and Mtn1 to Dp(Mtn1), are accompanied by an overall 5- to 6-fold increase of RNA accumulation. The two changes seem to have occurred in non-African populations since Mtn.3 but not Mtn1 was detected in our sample from tropical Africa, while Mtn1 and Dp (Mtn1) are prevalent in European and North American samples.

ACE2, an activator of yeast metallothionein expression which is homologous to SWI5

Transcription of the Saccharomyces cerevisiae metallothionein gene CUP1 is induced in response to high environmental levels of copper. Induction requires the ACE1 gene product, which binds to specific sites in the promoter region of the CUP1 gene. In this study, we found that deleting the entire coding sequence of the ACE1 gene resulted in a decrease in basal-level transcription of CUP1 to low but detectable levels and conferred a copper-sensitive phenotype to the cells. We have isolated a gene, designated ACE2, which when present on a high-copy-number plasmid suppresses the copper-sensitive phenotype of an ace1-deletion strain. The presence of multiple copies of the ACE2 gene enhanced expression of an unlinked CUP1-lacZ fusion integrated in the yeast genome and resulted in an increase in the steady-state levels of CUP1 mRNA in an ace1-deletion background. A large deletion of the coding region of the genomic copy of ACE2 resulted in a decrease in steady-state levels of CUP1 mRNA, indicating that ACE2 plays a role in regulating basal-level expression of CUP1. The ACE2 open reading frame encodes a polypeptide of 770 amino acids, with putative zinc finger structures near the carboxyl terminus. This protein is 37% identical to the SWI5 gene product, an activator of HO gene transcription in S. cerevisiae, suggesting that ACE2 and SWI5 may have functional similarities.

ACE2, an activator of yeast metallothionein expression which is homologous to SWI5

Transcription of the Saccharomyces cerevisiae metallothionein gene CUP1 is induced in response to high environmental levels of copper. Induction requires the ACE1 gene product, which binds to specific sites in the promoter region of the CUP1 gene. In this study, we found that deleting the entire coding sequence of the ACE1 gene resulted in a decrease in basal-level transcription of CUP1 to low but detectable levels and conferred a copper-sensitive phenotype to the cells. We have isolated a gene, designated ACE2, which when present on a high-copy-number plasmid suppresses the copper-sensitive phenotype of an ace1-deletion strain. The presence of multiple copies of the ACE2 gene enhanced expression of an unlinked CUP1-lacZ fusion integrated in the yeast genome and resulted in an increase in the steady-state levels of CUP1 mRNA in an ace1-deletion background. A large deletion of the coding region of the genomic copy of ACE2 resulted in a decrease in steady-state levels of CUP1 mRNA, indicating that ACE2 plays a role in regulating basal-level expression of CUP1. The ACE2 open reading frame encodes a polypeptide of 770 amino acids, with putative zinc finger structures near the carboxyl terminus. This protein is 37% identical to the SWI5 gene product, an activator of HO gene transcription in S. cerevisiae, suggesting that ACE2 and SWI5 may have functional similarities.