Cadmium contaminated soil affects retinogenesis in lizard embryos.

Lizards are soil surface animals that represent an important link between invertebrates and higher predators. Being part of wild fauna, they can be affected by contamination from anthropic activities and in particular, pesticides and chemical substances of various nature that reach the soil surface directly or through fall out. Among these substances, heavy metals such as cadmium may exert particularly marked toxic effect on both adult and embryos. In lizards, recent studies show that cadmium may cause developmental defects, including alteration of eye development, with appearance of unilateral microphthalmia and retinal folding. In the present study, the effects of cadmium incubation on retinal development were investigated demonstrating that cadmium interferes with cell cycle regulation by increasing proliferation. An increased expression of Otx2 and Pax6 genes, markers of retinal differentiation, was also found. However, the cellular localization of Pax6 and Otx2 transcripts did not change in treated embryos: in the early stages of retinogenesis, the two genes were expressed in all retinal cells; in the differentiated retina, Otx2 remained in the cellular bodies of retinal cells forming the nuclear and the ganglion layers, whereas Pax6 was expressed only in the cells of the inner nuclear and the ganglion layers. Data suggest that the increased expression of Pax6 and Otx2 could be ascribed to the hyperproliferation of retinal cells rather than to an effective gene overexpression.

Cadmium impairment of reproduction in the female wall lizard Podarcis sicula.

The exposure to environmental toxicants such cadmium (Cd) is an important research area in wildlife protection. In this study, the effect of Cd oral administration on the ovarian structure and function and on reproductive performance of the Italian wall lizard Podarcis sicula was studied. In vivo, adult female lizards were randomly assigned to three groups. Cd was given with food in single dose and in multiple doses 3 days/week for 4 weeks at dose of 1.0 µg/g body weight. Following euthanasia, the ovaries were removed and analyzed for morpho-functional changes. Results demonstrated that Cd increases prefollicular germ cells number; the evaluation of the number of follicles detects significantly higher number of atretic growing follicles, whereas primary follicles remain unchanged with respect to controls. After Cd treatments, follicles are deformed by the presence of large protrusions and a general dysregulation in the follicle organization is observed. The zona pellucida is also affected. Cd causes alteration in sugar metabolism and in metallothionein gene expression. Finally, Cd administration significantly reduces clutch size and dramatically increases embryo mortality. In conclusion, data here described show that Cd induces morpho-functional alterations in lizard follicles and indicates that these are responsible for a significant impairment of oogenesis. The effects of the dose are time independent, persisting essentially unchanged regardless of single or multiple administration, so it can be concluded that even occasional, sublethal Cd contamination may significantly impair reproductive performance in these animals.

Cadmium-induced teratogenicity in lizard embryos: correlation with metallothionein gene expression.

Cadmium teratogenic effects and metallothionein expression were studied in tissues of lizard embryos at different stages of development. Incubation of eggs in cadmium contaminated soil had no effect on embryo survival, but strongly affected cranial morphogenesis. Cytological analyses demonstrated abnormalities in the development of proencephalic vesicles, mesencephalon and eyes. No defects were observed in somite or limb development. Northern blot analysis demonstrated that MT expression was much stronger in embryos developed in cadmium contaminated soil. In situ hybridization showed an early induction of MT gene expression in developing liver and gut, whereas in brain and eyes the spatial and temporal localization of MT transcripts did not change. A possible correlation between inability to induce MT expression and abnormalities observed in the head region of lizard developing embryos is suggested.

Spatiotemporal changes in metallothionein gene expression during embryogenesis in the wall lizard Podarcis sicula.

Lizard embryos are nutritionally independent from their environment. During the early phases of oogenesis, the egg prepares for development by storing reserve organelles, proteins, and RNAs sufficient to allow the zygote to transform into a juvenile. This preparation also includes the storage of metallothionein (MT) transcripts. This study investigated the localization of these transcripts by in situ hybridization throughout Podarcis sicula developmental stages. Our data show that MT expression undergoes shifts in both regional and cellular localization. MT transcripts were detected early in the central nervous system, later in tissues implicated in metabolic processes. Results are discussed highlighting differences in lizard embryonic spatial and temporal MT expression compared with piscine, amphibian, and mammalian embryos. We hypothesize that, under natural conditions, the nutritionally closed system represented by the lizard egg protects the developing embryo from an unwanted excess of metals. This mechanism would make MT expression and accumulation in detoxifying organs in developing animals unnecessary until hatching and food intake begins. Conversely, the presence of MT transcripts during brain development may ensure the correct final architecture of this organ.

Responses to cadmium intoxication in the liver of the wall lizard Podarcis sicula.

This study examined the cytological and molecular effects of cadmium, a toxic heavy metal, in the liver of the Italian wall lizard Podarcis sicula. Cadmium was administered in single dose, by diet, to induce a concentration comparable with that measured in animals living in contaminated sites. For comparison, cadmium was also administered in multiple doses by food (chronic) or in a single dose intraperitoneally (i.p.); the effects were followed at regular time intervals up to 30 days post treatments. Atomic absorption spectrometry analysis demonstrated cadmium ion uptake and accumulation in the parenchyma with an estimated half-life of approximately 8 days. Cytological analyses revealed that the metal induced oedema, activated metallothionein expression in Kupffer cells and extracellular matrix production in fat storing cells. It also caused swelling and alteration in lipid and sugar metabolism in hepatocytes. In conclusion, in the wall lizard cadmium is toxic to the liver even at very low concentrations, the response is not strictly dose and time dependent and almost no recovery occurs in short (30 days) time periods.

Differential gene expression profiles in embryos of the lizard Podarcis sicula under in ovo exposure to cadmium.

Screening for differentially expressed genes is a straightforward approach to study the molecular basis of contaminant toxicity. In this paper, the mRNA differential display technique was applied to analyze transcriptional regulation in response to cadmium exposure in the lizard embryos. Lizard eggs may be particularly susceptible to soil contamination and in ovo exposure may interfere or disrupt normal physiological function in the developing embryo, including regulation of gene expression. Fertilized eggs of the lizard Podarcis sicula were incubated in cadmium-contaminated soil at 25 degrees C for 20 days. Gene expression profiling showed 5 down- and 9 up-regulated genes. Four cDNAs had no homology to known gene sequences, thus suggesting that may either encode not yet identified proteins, or correspond to untranslated regions of mRNA molecules. Four fragments exhibited significant sequence similarity with genes encoding novel proteins or ESTs derived from other vertebrates. The remaining genes are mainly involved in molecular pathways associated with processes such as membrane trafficking, signal transduction, cytoskeletal organization, cell proliferation and differentiation. Cadmium also affected the expression of factors actively involved in the regulation of the transcription machinery. Down-regulated genes are mainly associated with cellular metabolism and cell-cycle regulation and apoptosis. All of these differentially expressed genes may represent candidates that function in cadmium responses. The present study leads to an increased understanding of genes and/or the biochemical pathways involved in perturbation of embryo development following cadmium exposure.

Molecular cloning and sequencing of metallothionein in squamates: new insights into the evolution of the metallothionein genes in vertebrates.

Metallothioneins are cysteine-rich, metal-binding proteins ubiquitously expressed in living organisms. In the last past years, a plethora of vertebrate metallothionein sequences have become available, but so far there has been an almost absolute lack of data about sequences of metallothionein of non-avian diapsida. In the framework of the investigations on structural and functional properties of non-mammalian metallothioneins, we have cloned and sequenced the cDNAs encoding for metallothioneins of 10 squamate reptiles, belonging to 5 different infraorders. These sequences have been used to gain insight into the evolutionary history of metallothioneins in reptiles. Phylogenetic analysis shows that reptilian metallothionein phylogeny is inconsistent with the species phylogeny. Such findings allow us to hypothesize that the identified metallothionein in each squamate species used for this study might be considered a paralogous gene derived from more events of gene duplication and losses occurred during the diversification of the squamate species. Finally, through vertebrate metallothionein comparisons and phylogenetic analysis, we also add a novel contribution to the understanding of the evolution of metallothionein genes along the major vertebrate lineages.

cGnRH II involvement in pyriform cell apoptosis.

We have investigated whether gonadotrophin-releasing hormone (GnRH) is involved in triggering the apoptotic death of pyriforms, the nurse cells that cooperate in oocyte growth during mid- to late previtellogenesis in the lizard Podarcis sicula. Our immunocytochemical analyses demonstrate that pyriforms express GnRH receptors and that, in late previtellogenesis, they are up-regulated by cGnRH II. The hormone however does not trigger receptor synthesis and activation, events that therefore must be under the control of other regulatory factors. Our results also indicate that in vitro treatment of pyriforms with cGnRH II induces DNAse I activation and DNA laddering, clear cytological evidence of apoptosis, but not Fas/Fas-L synthesis or caspase activation. We conclude that cGnRH II is pro-apoptotic to pyriform cells and that it exerts its effects by activating an alternative cell death pathway, probably involving calcium as first messenger and DNase I as first executioner.

The immunomodulatory protein SV-IV protects serum-deprived cells against apoptosis but not against G0/G1 arrest: possible implications for the survival of implanting embryo.

Serum deprivation induced in human lymphoblastoid Raji cells oxidative stress-associated apoptotic death and G0/G1 cell cycle arrest. Addition into culture medium of the immunomodulatory protein Seminal vesicle protein 4 (SV-IV) protected these cells against apoptosis but not against cycle arrest. The antiapoptotic activity was related to: (1) decrease of endocellular reactive Oxygen species (ROS) (2) increase of mRNAs encoding anti-oxidant enzymes (catalase, G6PD) and antiapoptotic proteins (survivin, cox-1, Hsp70, c-Fos); (3) decrease of mRNAs encoding proapoptotic proteins (c-myc, Bax, caspase-3, Apaf-1). The biochemical changes underlaying these effects were probably induced by a protein tyrosine kinase (PTK) activity triggered by the binding of SV-IV to its putative plasma membrane receptors. The ineffectiveness of SV-IV to abrogate the cycle arrest was accounted for by its downregulating effects on D1,3/E G1-cyclins and CdK2/4 gene expression, ppRb/pRb ratio, and intracellular ROS concentration. In conclusion, these experiments: (1) prove that SV-IV acts as a cell survival factor; (2) suggest the involvement of a PTK in SV-IV signaling; (3) point to cell cycle-linked enzyme inhibition as responsible for cycle arrest; (4) provide a model to dissect the cycle arrest and apoptosis induced by serum withdrawal; (5) imply a possible role of SV-IV in the survival of hemiallogenic implanting embryos.

Block of mitochondrial apoptotic pathways in lizard ovarian follicle cells as an adaptation to their nurse function.

Pyriforms are ovarian follicle nurse cells that undergo apoptosis at the end of previtellogenesis and are completely eliminated by the epithelium. This event is accompanied by the active transfer of organelles and macromolecules to the oocyte via an intercellular bridge. Since it would be a nonsense for damaged mitochondria to reach the oocyte, we have postulated that pyriform cells have adapted their apoptotic machinery to prevent mitochondrial degradation. To verify this hypothesis, we have studied mitochondrial morphology and functionality during follicle cell regression. Cytological and biochemical evidence indicates that mitochondria in pyriforms maintain their size, organization and membrane potential. This clearly indicates that they are not involved in apoptosis signalling/progression. This block would favour both the oocyte, by increasing the pool of organelles available from follicle cells, and also the regressing pyriforms, by maintaining the energy resources required for completion of their nurse function. The block is probably attributable to an over-expression of Bcl-2 and might be carried out by sequestering cytochrome c inside the organelles. As demonstrated by in vitro experiments, the mitochondrial apoptosis pathway can be activated by stress induction, such as serum deprivation, but not following physiological pro-apoptotic signalling, such as treatment with gonadotrophin-releasing hormone.

Cadmium distribution and metallothionein expression in lizard tissues following acute and chronic cadmium intoxication.

The present report is an attempt to investigate the influence of intraperitoneal and dietary cadmium exposure on the distribution of cadmium accumulation and induction of metallothionein gene expression in different tissues of the lizard Podarcis sicula. Cadmium accumulation in liver, kidney, ovary, brain and intestine was measured by atomic absorption spectrometry. Metallothionein gene induction was determined by dot blot analyses on the total RNA extracted from the same organs. Our data indicate that cadmium exposure results in significant cadmium uptake, but the patterns of this uptake varies with organ and exposure route. After a single intraperitoneal treatment, concentrations of cadmium and metallothionein transcript are positively correlated in kidney, liver and ovary. Following a dietary cadmium treatment, a positive correlation between the increase of metallothionein mRNA and cadmium accumulation is found in intestine, ovary and kidney, while no correlation is present in liver and brain.

Evolutionary fate of duplicate genes encoding aspartic proteinases. Nothepsin case study.

Gene duplication is considered an important evolutionary mechanism leading to new gene functions. According to the classical model, one gene copy arising from gene duplication retains the ancestral function, whilst the other becomes subject to directional selection for some novel functions. Hence, according to this model, long-term persistence of two paralogous genes is possible only with the acquisition of functional innovation. In the absence of neofunctionalization, one of the duplicate genes may be lost following accumulation of deleterious mutations, ultimately leading to the loss of function. Recently, new mechanisms have been proposed according to which both paralogs are maintained without apparent neofunctionalization. In this paper we describe the molecular evolution of the aspartic proteinase gene family, with particular regard for the nothepsin gene, a sex- and tissue-specific form of aspartic proteinase active in fish. The finding of nothepsin in a reptile is indicative of the presence of this gene in organisms other than fish. However, the failure to find any nothepsin-like gene in avian, murine and human genome suggests that the gene has been lost in certain lineages during evolution. At variance with piscine nothepsin expressed exclusively in female liver under the estrogens action, the reptilian counterpart lacks both tissue and sex specificity, as it is constitutively expressed in different tissues of male and female specimens. The expression of the nothepsin gene in fish and lizard is accompanied by the expression of a paralogous gene encoding for cathepsin D. Functional divergence analysis indicates that cathepsin D accumulated amino acid substitutions, whereas nothepsin retained most of the ancestral functions. Phylogenetic analysis shows a preponderance of replacement substitutions compared to silent substitutions in the branch leading to the cathepsin D clade, whilst nothepsin evolves under negative selection. To explain the loss of the nothepsin gene in certain lineages, we propose a model that takes into account the complementary degenerative mutations occurring in regulatory elements of the promoter regions of the two genes. According to this model, gene loss occurs whenever the two genes acquire the same expression pattern. The coexistence of cathepsin D and nothepsin is explained in terms of metabolic cooperation of the two enzymes.

Accumulation of zinc, copper, and metallothionein mRNA in lizard ovary proceeds without a concomitant increase in metallothionein content.

The possible role of metallothionein (MT) in metal homeostasis has been investigated in growing oocytes and eggs of the lizard Podarcis sicula. Chromatographic analysis does not reveal the presence of MT in both ovary and eggs, the only metal-binding proteins detected being represented by high molecular mass components. De novo synthesis of MT could be observed in the ovary of cadmium-treated lizards. A cDNA encoding MT was obtained from the liver of P. sicula by RT-PCR followed by a RACE strategy, using primers designed on consensus motifs of vertebrate MT. In spite of the lack of MT in the ovary of untreated animals, Northern blot analysis demonstrates that the maternal untranslated MT transcript is expressed constitutively in the ovary in all the periods of the ovarian cycle. MT mRNA content increases during the oocyte growth, reaching the highest level in ovulated eggs, concomitantly with the accumulation of zinc and copper. Our findings suggest that maternal MT mRNA accumulates in the egg and is translated sometime during development to cope with the future needs of the growing embryo. The appearance of MT after cadmium treatment suggests that the block that makes the oocytarian MT mRNA untranslatable is removed by the metal.

Changes in zinc, copper and metallothionein contents during oocyte growth and early development of the teleost Danio rerio (zebrafish).

In the present report, we investigated zinc, copper and metallothionein (MT) contents in zebrafish oocytes and embryos. Our results demonstrate that the metal content increases during oocytes maturation. Zinc increases from 30 ng/oocyte (stage-1 oocytes) to 100 ng/oocyte (stage-3 oocytes); copper varied from 1 ng/oocyte (stage-1 oocytes) to 3.5 ng/oocyte (stage-3 oocytes). During embryogenesis, zinc and copper contents dramatically increase after fertilisation around the 512-cells stage, then slowly decrease until the mid-gastrula stage. During oocyte growth, the changes in the MT level are proportional to metal content, whereas during embryogenesis the pattern of MT accumulation does not parallel that of the two metals. Indeed, the maternal pool of MT decreases steadily during the early stages of the development until the gastrula stage. We have examined the effect of cadmium on the expression of MT during zebrafish development. After cadmium exposure, MT content increases in embryos at the blastula stage, whereas no induction occurs in embryos at the gastrula stage. However, pre-treatment of embryos at the gastrula stage with 5-aza-2'-deoxycytidine induces MT synthesis following exposure to cadmium. These observations show that changes in metal levels are not correlated to MT content in the embryo, whereas DNA methylation is one of the factors regulating MT expression.

Oestrogen-induced expression of a novel liver-specific aspartic proteinase in Danio rerio (zebrafish).

Aspartic proteinases are a group of endoproteolytic proteinases active at acidic pH and characterized by the presence of two aspartyl residues in the active site. They include related paralogous proteins such as cathepsin D, cathepsin E and pepsin. Although extensively investigated in mammals, aspartic proteinases have been less studied in other vertebrates. In a previous work, we cloned and sequenced a DNA complementary to RNA encoding an enzyme present in zebrafish liver. The sequence resulted to be homologous to a novel form of aspartic proteinase firstly described by us in Antarctic fish. In zebrafish, the gene encoding this enzyme is expressed only in the female liver, in contrast with cathepsin D that is expressed in all the tissues examined independently of the sex. For this reason we have termed the new enzyme liver-specific aspartic proteinase (LAP). Northern blot analyses indicate that LAP gene expression is under hormonal control. Indeed, in oestrogen-treated male fish, cathepsin D expression was not enhanced in the various tissues examined, but the LAP gene product appeared exclusively in the liver. Our results provide evidence for an oestrogen-induced expression of LAP gene in liver. We postulate that the sexual dimorphic expression of the LAP gene may be related to the reproductive process.

Relationship between adenylate cyclase sensitivity to follitropin and FSH receptor mRNA expression in the ovary of the lizard Podarcis sicula.

In mammals, gonadal functions are regulated by two pituitary gonadotropins, follicle-stimulating hormone (FSH) and luteinizing hormone (LH), that interact with gonadal membrane receptors to activate adenylate cyclase. In comparison to mammalian systems, in squamate reptiles a reduced amount of information exists on gonadotropins and their related receptors. This study is aimed at clarifying if, in the lizard Podarcis sicula, the ovarian sensitivity to FSH is correlated to the reproductive cycle and to the expression of membrane receptors involved in the hormone recognition. The results demonstrate that the ovarian adenylate cyclase responsiveness to FSH parallels ovarian functions, being maximal during the ovulatory period. The ovarian sensitivity to FSH is also related to oocyte growth and vitellogenesis. Northern blot analyses reveal that the FSH receptor mRNA is maximally expressed in vitellogenic oocytes during the reproductive period. These results suggest that, in lizard ovary, hormone activation of adenylate cyclase is mediated by de novo synthesis of receptors specifically involved in FSH recognition. In lizards treated in vivo with FSH during the pre-ovulatory period, adenylate cyclase becomes refractory to further FSH stimulation 2 hr after treatment, but sensitivity to the hormone is restored after 2 weeks. Nevertheless, while the restored level of activity never exceeds that observed during the nonreproductive period, the expression level of FSH receptor mRNAs is significantly enhanced in these animals. These results suggest that in lizard the processes that regulate ovarian growth, vitellogenesis, and ovulation are controlled by a complex network of signals including gonadotropin, FSH receptor expression, and adenylate cyclase.

High affinity copper transport protein in the lizard Podarcis sicula: molecular cloning, functional characterization and expression in somatic tissues, follicular oocytes and eggs.

Copper (Cu) is an essential element required in many biological processes including cellular growth and development. The molecular mechanisms involved in copper homeostasis include proteins that play a role in Cu uptake. Genes encoding high affinity copper transporters (Ctr) have been identified in yeast, plant and mammalian cells. Analysis of copper and zinc content in growing ovarian follicles and ovulated eggs of the reptilian Podarcis sicula demonstrated that the levels of both metals rise during oocyte growth, reaching the maximum in ovulated eggs. By exploiting the remarkable evolutionary conservation of the primary structure of Ctr proteins, cDNA encoding a Ctr was isolated from the liver of the lizard P. sicula by reverse transcriptase PCR and RACE strategy by using primers designed based on consensus motifs present in mammalian Ctr. The predicted protein sequence contains three transmembrane domains and a putative hydrophilic extracellular amino-terminal domain. Besides complementing the respiratory deficiency of yeast cells defective in high affinity Cu transport, expression of lizard Ctr1(1) in Hek293 cells stimulates Cu uptake.Gene expression assessed by Northern blot hybridization of RNA from different tissues of P. sicula shows the highest levels of transcript in both intestine and liver. The profile of Ctr1 mRNA in growing ovarian follicles and eggs demonstrates that the transcript accumulates during the oocyte growth and reaches the highest levels in ovulated eggs. These results suggest that lizard Ctr1 protein may function in Cu acquisition in growing oocytes and eggs.

Effect on Inhibition of Micromere Segregation on the Mitotic Pattern in the Sea Urchin Embryo: (micromeres/mitotic pattern/sea urchin).

Detergent treatment of sea urchin eggs at the mid 4-cell stage results in prevention of micromere segregation at the fourth cleavage. In these embryos not only the formation of the primary mesenchyme is suppressed, but synchrony of cell division, which is the rule during the first four cleavage cycles, continues for several cycles after the 16-cell stage while the typical mitotic phase wave that sets in after micromere segregation is abolished. These results support the hypothesis that micromeres act as coordinators of the mitotic activity of the embryo.