Comparative morphological studies of yeast cells using automated image analysis

The ultrastructural alterations in cells of Candida utilis caused by the influence of copper ions have been studied by means of quantitative image analysis. A model has been proposed which presents the following informations: The main effect of the copper ions is represented by an increase of the volume of the whole cell and of that part of the cell which consists of nucleus, vacuoles, and inclusions (particles and globules). Nevertheless, neither the absolute volume of mitochondria, nor the density of mitochondria are influenced by high concentrations of copper ions in the culture medium.     

Antifungal Activity of Isothiocyanates and Related Compounds: III. Derivatives of Diphenyl, Stilbene, Azobenzene, and Several Polycondensed Aromatic Hydrocarbons

This paper presents the results of a study on the antifungal activity of isothiocyanates-derivatives of biphenyl (group "A"), of stilbene ("B"), of azobenzene and benzeneazonaphthalene ("C"), of naphthalene ("D"), and of further polycondensed aromatic hydrocarbons ("E"). From a total of 48 investigated compounds, antifungal activity was observed only in A and D group compounds. B, C, and E group derivatives are extremely insoluble in water, and the molecules are very large; as a result, they probably cannot pass into spores or mycelium of fungi. Thus, the -NCS group cannot manifest its reactivity.     

Modulation of intercellular communication during radiation and chemical carcinogenesis

Carcinogenesis is a multistep process, involving the irreversible conversion of a stem cell to a terminal-differentiation-resistant cell ("initiation"), followed by the clonal expansion of this cell ("promotion") and by the acquisition of other genetic alterations leading to malignancy ("progression"). The initiation and progression steps seem to be facilitated by mutagenesis. Promotion has been associated with agents and conditions that cause mitogenesis. Gap junctional intercellular communication, a fundamental biological process regulating cell growth and differentiation, has been postulated to play a major role in carcinogenesis. The hypothesis is supported by the fact that many cancer cells have some dysfunction in gap junctional intercellular communication, many tumor-promoting chemicals and several oncogenes (i.e., ras, src, mos, neu, but not myc) reduce gap junctional intercellular communication, and several growth factors (i.e., EGF, TGF-beta, bovine pituitary extract) inhibit gap junction function. This integrative concept postulates that chemical promoters, oncogenes coding for growth factors, receptors, or transmembrane signaling elements, and growth factors can isolate an initiated cell from the suppressing influence of surrounding normal cells by down-regulating the transfer of ions and small molecules through gap junctions.     

Fine structural localization of adenosine triphosphatase activities in the saccus vasculosus of the rainbow trout,Salmo gairdneri Richardson

The following characteristics of the adenosine triphosphatases (ATPase) in the saccus vasculosus were studied in Salmo gairdneri Richardson: 1) distributional pattern, 2) cytochemical properties in relation to different substrates, inhibitors, pH and bivalent metal ions, and 3) ultrastructural localization. Ultracytochemical studies using modifications of the Washstein-Meisel technique showed that within the pH range 7.1-8.0 several Mg++ or Ca++-activated ATPase are localized on the intracellular surface of membranes and in the cytoplasm of ependymal coronet cells and tanycytes ("supporting cells", "Zwischenzellen", glial cells"). The high ATPase activity at the level of the specialized luminal plasma membranes of coronet cell globules and of tanycyte microvilli is discussed in relation to phenomena of active transport and a possible resulting transfer of low-molecular weight substances into and/or from the cerebrospinal fluid (CSF). The localization of ATPase on the specialized membranes of primary vesicles is considered in connection with available structural and enzyme-cytochemical data on a possible function of these cell organelles in storage and release of substances (including Ca++ ions?). The cytoplasmic ATPase activity in coronet cells is ascribed to microtubules and/or possible existing contractile proteins/filaments, presumably concerned with internal transport or motility processes. In tanycytes ATPase activity is believed to be associated with the characteristic microfilamentous system of still unknown function. The ATPase activity in the (9 + 0) ciliary apparatus of globules could not be interpreted in terms of motility. The present study provides further support to the proposed hypothesis of the transport function of the saccus vasculosus, and an extension of the concept in the sense that not only the principal coronet cells, but also the tanycytes of this circumventricular organ are involved in CSF-homeostasis.     

Copper (II) accumulation and superoxide dismutase activity during growth of Aspergillus niger B-77

The influence of copper (II) ions on the growth, accumulation properties and superoxide dismutase (SOD) activity of a growing culture of Aspergillus niger B-77 were studied. Microbial growth, the level of copper (II) accumulation and SOD activity depended on the initial copper (II) concentration. Aspergillus niger is able to accumulate large amounts of copper (II) from the nutrient medium with 200 mg x l(-1) copper (II) ions without loosing its biological activities. Addition of copper (II) ions increased the SOD activity in the growing cell cultures. The changes in enzyme activity induced by heavy metal ions might be used as an indicator of intracellular oxy-intermediate generation in a cell culture growing under stress conditions.     

Pseudomonas bacteriophage phi KZ contains an inner body in its capsid

Electron microscopical examination of the new virulent bacteriophage phi KZ, specific for Pseudomonas aeruginosa, has revealed an unusual structure in its capsid. In the center of the phage head is a cylinder of low electron density ("inner body"), surrounded by fibrous material which is packed around the inner body in a spoollike manner. The inner body itself has a springlike appearance. These structures disappear after adsorption of phage particles to bacteria. Various morphological forms, which can be interpreted as intermediate steps in phi KZ DNA condensation, have been seen in ultrathin sections of phi KZ-infected cells.     

The different structures containing tight junction proteins in epidermal and other stratified epithelial cells, including squamous cell metaplasia

In stratified squamous epithelia constituent proteins of tight junctions (TJs) are not restricted to the zonula occludens-related structures of the uppermost living cell layer such as the stratum granulosum of the epidermis but TJ membrane proteins such as occludin and certain members of the claudin family as well as TJ plaque proteins, notably cingulin and protein ZO-1, have also been identified by immunofluorescence and immunoelectron microscopy in more basal layers where they form special cell-cell-connecting structures such as the "lamellated" and the "sandwich" junctions. In the present study, we describe another TJ protein-containing structure, the very small puncta occludentia ("stud junctions"), as the smallest identifiable TJ-like unit that occurs in most, perhaps all strata. We have also determined the specific distributions of TJ proteins in the cell layers of squamous cell metaplasias of the human bronchial tract. Moreover, we show that the occludin-related tetraspanin protein tricellulin-alpha connects and seals the membranes of adjacent "three corner" cell structures of the uppermost layer in keratinocytes growing in culture. We hypothesize the possible occurrence of tricellulin-beta in more basal cell layers of keratinocyte cultures and the general occurrence of different tricellulin splice forms in stratified epithelia in situ, and discuss the possible functions of TJ proteins in stratified epithelia and tumors derived therefrom.     

The utilization of copper and its role in the biosynthesis of copper-containing proteins in the fungus, Dactylium dendroides

Aspects of the utilization of copper by the fungus, Dactylium dendroides, have been studied. The organism grows normally at copper levels below 10 nM. Cells grown in medium containing 30 nM copper or less concentrate exogenous metal at all levels of added copper; copper uptake is essentially complete within 15 min and is not inhibited by cycloheximide, dinitrophenol or cyanide. These results indicate that copper absorption is not an energy-dependent process. The relationship between fungal copper status and the activities of three copper-containing enzymes, galactose oxidase, and extracellular enzyme, the cytosolic, Cu/Zn superoxide dismutase and cytochrome oxidase, has also been established. The synthesis of galactose oxidase protein (holoenzyme plus apo-enzyme) is independent of copper concentration. Cells grown in copper-free medium (less than 10 nM copper) excrete normal amounts of galactose oxidase as an apoprotein. At medium copper levels below 5 micrometer, new cultures contain enough total copper to enable the limited number of cells to attain sufficient intracellular copper to support hologalactose oxidase production. As a result of cell division, however, the amount of copper available per cell drops to a threshold of approx. 10 ng/mg below which point only apogalactose oxidase is secreted. Above 5 micrometer medium copper, holoenzyme secretion is maintained throughout cell growth. The levels of the Cu/Zn superoxide dismutase respond differently in that the protein itself apparently is synthesized in only limited amounts in copper-depleted cells. Total cellular superoxide dismutase activity is maintained under such conditions by an increase in activity associated with the mitochondrial, CN(-)-insensitive, manganese form of this enzyme. Cells grown at 10 micrometer copper show 83% of their superoxide dismutase activity to be contributed by the Cu/Zn form compared to a 17% contribution to the total activity in cells grown at 30 nM copper, indicating that the biosynthesis of the Cu/Zn and Mn-containing enzymes is coordinated. The data show that the level of copper modulates the synthesis of the cytosolic superoxide dismutase. In contrast, the cytochrome oxidase activity of D. dendroides is independent of cellular copper levels obtainable. Thus, the data also suggest that these three enzymes utilize different cellular copper pools. As cells are depleted of copper by cell division, the available copper is used to maintain Cu/Zn superoxide dismutase and cytochrome oxidase activity; at very low levels of copper, only the latter activity is maintained. The induction of the manganisuperoxide dismutase in copper-depleted cells should have practical value in the isolation of this protein.     

Functionally distinct classes of K+ sites on the (Na+ + K+)-dependent ATPase.

K+ interactions with a rat brain (Na+ + K+)-dependent ATPase and the associated K+-dependent nitrophenyl phosphatase activity were examined. Classes of sites for K+ were distinguished, initially, on the basis of affinity estimated by kinetic analysis in terms of KO.5 (the concentration for half-maximal activation), and by K+-accelerated enzyme inactivation by F-minus, which permits evaluation of a dissociation constant for K+, KD. Moderate-affinity sites ("alpha sites"), with a KD near 1 mM, were demonstrable for the phosphatase activity and for the "free" enzyme. High-affinity sites ("beta sites"), with a KD near 0.1 mM, were seen for the overall ATPase activity and under conditions in which enzyme phosphorylation by substrate also occurs. Further differentiation between alpha and beta sites was made in terms of (i) the characteristic changes in affinity with pH, and (ii) the efficacy of Li+ relative to K+, Rb+, Cs+, and Tl+ at these two classes of sites. Low-affinity sites ("gamma sites") through which K+ inhibits enzymatic activity were also detectable, with a KD around 140 mM. These data are incorporated into a model for the reaction sequence to accommodate both transport processes and certain K+/ATP antagonisms.     

Isolation and characterization of lipoproteins produced by human hepatoma-derived cell lines other than HepG2

A total of six established human hepatoma-derived cell lines, including Hep3B, NPLC/PRF/5 (NPLC), Tong/HCC, Hep 10, huH1, and huH2, were screened for their ability to accumulate significant quantities of lipoproteins in serum-free medium. Only two cell lines, Hep3B and NPLC, secreted quantitatively significant amounts of lipoproteins. In a 24-h period the accumulated mass of apolipoproteins (apo) A-I, A-II, B, and E and albumin for Hep3B cells was 1.96, 1.01, 1.96, 1.90, and 53.2 micrograms/mg cell protein per 24 h, respectively. NPLC cells secreted no detectable albumin but the 24-h accumulated mass for apolipoproteins A-I, A-II, B, and E was 0.45, 0.05, 0.32, and 0.68 micrograms/mg cell protein per 24 h, respectively. Twenty four-hour serum-free medium of Hep3B cells contained lipoproteins corresponding to the three major density classes of plasma; percent protein distribution among the lipoprotein classes was 4%, 41%, and 56% for very low density lipoprotein ("VLDL"), low density lipoprotein ("LDL"), and high density lipoprotein ("HDL"), respectively. NPLC was unusual since most of the lipoprotein mass was in the d 1.063-1.235 g/ml range. Hep3B "LDL", compared with plasma LDL, contained elevated triglyceride, phospholipid, and free cholesterol. Nondenaturing gradient gel electrophoresis revealed that Hep3B "LDL" possessed a major component at 25.5 nm and a minor one at 18.3 nm. Immunoblots showed that the former contained only apoB while the latter possessed only apoE. Like plasma VLDL, Hep3B "VLDL" particles (30.5 nm diameter) isolated from serum-free medium contained apoB, apoC, and apoE. "HDL" harvested from Hep3B and NPLC medium were enriched in phospholipid and free cholesterol and poor cholesteryl ester which is similar to the composition of HepG2 "HDL." "HDL" from Hep3B and NPLC culture medium on gradient gel electrophoresis had peaks at 7.5, 10, and 11.9 nm which were comparable to major components found in HepG2 cell medium. Hep3B cells, in addition, possessed a particle that banded at 8.2 nm which appeared to be an apoA-II without apoA-I particle by Western blot analysis. The cell line also produced a subpopulation of larger-sized "HDL" not found in HepG2 medium. NPLC "HDL" had a distinct peak at 8.3 nm which by Western blot was an apoE-only particle. Electron microscopy revealed that "HDL" harvested from Hep3B and NPLC medium consisted of discoidal and small, spherical particles like those of HepG2. The "HDL" apolipoprotein content of each cell line was distinct from that of HepG2. ApoA-II at 35% of apolipoprotein distinguishes Hep3B "HDL" from HepG2, which contains only 10%.(ABSTRACT TRUNCATED AT 400 WORDS)     

Variability of DNA markers in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> cultured cells under standard growing conditions and under the influence of stressors

We investigated the genetic heterogeneity of two A. thaliana callus lines, which had been cultured in vitro, respectively, for 6 months and 8 years under standard conditions and after exposure to abiotic stressors (high temperature, anoxia, and toxic copper ions). Under standard culture conditions, the level of genetic diversity identified by AFLP was 1.2% for the six-month-old callus and 5% for the older cultivated one. In stress conditions, we observed a decrease in the level of genetic diversity of cells in both of the lines analyzed. There was no conclusive evidence of the induction of changes in the DNA nucleotide sequence under the influence of unfavorable conditions. The effect of stressors was manifested primarily at the level of cell populations and was expressed as a selection of cells with certain genotypes.     

Autoradiographic study of the proliferative activity of the preoptic recess ependyma in yearling and juvenile common frogs

Proliferative activity of the ependyma, lining the recessus praeopticus in juvenile frogs was studied with 3H-thymidine radioautography. Usually much more pronounced proliferation of ependymal cells occurred in the preoptic region in one year old frogs as compared with two year old ones. It can be concluded that in the former animals the migration of postmitotic labeled cells into the subependymal zone of the recessus preoptic area is significantly more intense. By the 30th day after multiple isotope injections some newly formed neurosecretory cells with labeled nuclei were found in the 1-5 cellular position of the recessus praeopticus subependymal zone. It is postulated that in juvenile frogs the ependyma of lateral wall of recessus praeopticus is probably a source ("cambium"), from which some young neurosecretory cells may originate.     

The utilization of copper and its role in the biosynthesis of copper-containing proteins in the fungus, Dactylium dendroides

Aspects of the utilization of copper by the fungus, Dactytium dendroides, have been studied. The organism grows normally at copper levels below 10 nM. Cells grown in medium containing 30 nM copper or less concentrate exogenous metal at all levels of added copper; copper uptake is essentially complete within 15 min and is not inhibited by cycloheximide, dinitrophenol or cyanide. These results indicate that copper absorption is not an energy-dependent process. The relationship between fungal copper status and the activities of three copper-containing enzymes, galactose oxidase, an extracellular enzyme, the cytosolic, Cu/Zn superoxide dismutase and cytochrome oxidase, has also been established. The synthesis of galactose oxidase protein (haloenzyme plus apo-enzyme) is independent of copper concentration. Cells grown in copper-free medium (< 10 nM copper) excrete normal amounts of galactose oxidase as an apoprotein. At medium copper levels below 5 μM, new cultures contain enough total copper to enable the limited number of cells to attain sufficient intracellular copper to support hologalactose oxidase production. As a result of cell division, however, the amount of copper available per cell drops to a threshold of approx. 10 ng/mg below which point only apogalactose oxidase is secreted. Above 5 μM medium copper, holoenzyme secretion is maintained throughout cell growth.The levels of the Cu/Zn superoxide dismutase respond differently in that the protein itself apparently is synthesized in only limited amounts in copper-depleted cells. Total cellular superoxide dismutase activity is maintained under such conditions by an increase in activity associated with the mitochondrial, CN^?-insensitive, manganese form of this enzyme. Cells grown at 10 μM copper shown 83% of their superoxide dismutase activity to be contributed by the Cu/Zn form compared to a 17% contribution to the total activity in cells grown at 30 nM copper, indicating that the biosynthesis of the Cu/Zn and Mn-containing enzymes is coordinated. The data show that the level of copper modulates the synthesis of the cytosolic superoxide dismutase. In contrast, the cytochrome oxidase activity of D. dendroides is independent of cellular copper levels obtainable. Thus, the data also suggest that these three enzymes utilize different cellular copper pools. As cells are depleted of copper by cell division, the available copper is used to maintain Cu/Zn superoxide dismutase and cytochrome oxidase activity; at very low levels of copper, only the latter activity is maintained. The induction of the manganisuperoxide dismutase in copper-depleted cells should have practical value in the isolation of this protein.     

Role of haematopoietic cells and endothelial progenitors in tumour angiogenesis

Bone marrow-derived cells include haematopoietic cell lineages and the recently described endothelial progenitor cells (EPCs). It has been recently emphasised that these marrow-derived cells contribute to tumour angiogenesis, and different mechanisms have been proposed that account for this activity. Whereas haematopoietic cells may promote tumour angiogenesis through the release of proangiogenic factors or by creating permissive conditions in the tumour microenvironment that favour the growth of locally derived blood vessels ("paracrine" role), endothelial progenitors are thought to directly incorporate into nascent blood vessels as bona fide endothelial cells ("building block" role). The relative contribution of these distinct pathways to tumour angiogenesis is the subject of intense investigation and debate.     

Cholesterol-induced growth stimulation, macromolecule synthesis, and increased phosphoinositide metabolism of ascites tumour cells in culture

Ascites tumour cells have previously been shown by us to require exogenous cholesterol for growth. To investigate further this phenomenon, we have used, in addition to free cholesterol, cholesterol complexed to digitonine, to elaborate the specificity of this growth-controlling process using a chemically defined medium. Our data show that only free cholesterol stimulates cell growth and macromolecule synthesis in a dose-dependent manner, suggesting that the proper embedding of the sterol into the membrane is a prerequisite for its function. Furthermore, studies have been performed on the influence of cholesterol on the phosphoinositide metabolism of our cells, as phosphoinositides furnish important second messenger molecules in the cascade of signal transduction. We could show that cholesterol stimulates a transient release of inositol trisphosphate and other inositol phosphates by inducing the activation of phospholipase C (PLC). PLC activation by a factor of about 3 with phosphatidylinositol 4-phosphate and phosphatidyl inositol 4,5-bisphosphate as substrates could be measured directly by using a partially purified membrane preparation. This enzyme activity was found to be strongly dependent on free Ca2+ ions with optimal concentrations of 100 nM for cholesterol- and 50 nM for cholesterol-digitonide-treated cells. Ca2+ concentration for half-maximum activation, however, was identical under both conditions. Phospholipase C activity could be synergistically increased about 2-fold with 25 microg GTP gammaS in cholesterol-digitonide-treated cells as well, suggesting that the coupling between phospholipase C and the G-protein was not disturbed by the complex. These data demonstrate a functional role of cholesterol on cell growth, macromolecule synthesis, and phosphoinositide metabolism mediating the release of important second messenger molecules.     

Calcium pectate chemistry controls growth rate of Chara corallina

Pectin, a normal constituent of cell walls, caused growth rates to accelerate to the rates in living cells when supplied externally to isolated cell walls of Chara corallina. Because this activity was not reported previously, the activity was investigated. Turgor pressure (P) was maintained in isolated walls or living cells using a pressure probe in culture medium. Pectin from various sources was supplied to the medium. Ca and Mg were the dominant inorganic elements in the wall. EGTA or pectin in the culture medium extracted moderate amounts of wall Ca and essentially all the wall Mg, and wall growth accelerated. Removing the external EGTA or pectin and replacing with fresh medium returned growth to the original rate. A high concentration of Ca2+ quenched the accelerating activity of EGTA or pectin and caused gelling of the pectin, physically inhibiting wall growth. Low pH had little effect. After the Mg had been removed, Ca-pectate in the wall bore the longitudinal load imposed by P. Removal of this Ca caused the wall to burst. Live cells and isolated walls reacted similarly. It was concluded that Ca cross-links between neighbouring pectin molecules were strong wall bonds that controlled wall growth rates. The central role of Ca-pectate chemistry was illustrated by removing Ca cross-links with new pectin (wall "loosening"), replacing vacated cross-links with new Ca2+ ("Ca2+-tightening"), or adding new cross-links with new Ca-pectate that gelled ("gel tightening"). These findings establish a molecular model for growth that includes wall deposition and assembly for sustained growth activity.     

Copper chelates as probes of biological systems: stable copper complexes with a macrocyclic bifunctional chelating agent

Monoclonal antibodies tagged with chelated metal ions have numerous potential applications. Here we report the synthesis of a new "bifunctional" metal chelator, 6(p-bromoacetamidobenzyl)-1,4,8,11-tetraazacyclotetradecane- N,N',N",N"' -tetraacetic acid, which can be covalently attached to proteins and which binds copper stably in human serum under physiological conditions. In contrast, other reagents based on ethylenediaminetetraacetic acid or diethylenetriaminepentaacetic acid rapidly lose copper to serum albumin under the same conditions.     

Regulation of gene expression in preimplantation mouse embryos: effects of the zygotic clock and the first mitosis on promoter and enhancer activities

Previous studies have reported that promoters requiring enhancers for full activity in mammalian somatic cells also require enhancers when injected into mouse two-cell embryos, whereas the same promoters can be expressed just as efficiently in the absence of an enhancer when injected into arrested one-cell embryos. Experiments were designed to determine whether this phenomenon reflected normal developmental changes at the beginning of mammalian development, or simply differences in the physiological states of these cells under the experimental conditions employed. The activity of three different promoters that function in a wide variety of mammalian cells was measured both in embryos whose morphological development was arrested and in embryos that continued development in vitro. Expression of the injected gene was related to the onset of zygotic gene expression ("zygotic clock"), the phase of the cell proliferation cycle, the use of aphidicolin to arrest cell proliferation, and formation of two-cell embryos in vitro and in vivo. The results demonstrated that promoter activity was tightly linked to zygotic gene expression, while the need for enhancers to stimulate promoter activity depended only on formation of a two-cell embryo. These results further support the hypothesis that the first mitosis induces a general repression of promoters prior to initiation of zygotic gene expression that is relieved specifically by enhancers.     

Excess copper effect on growth, chloroplast ultrastructure, oxygen-evolution activity and chlorophyll fluorescence in Glycine max cell suspensions

The influence of excess copper on soybean photosynthetic cell suspensions was investigated. The cell suspensions grew well in the presence of 5–20 µ M CuSO₄ and developed tolerance to even higher levels of CuSO₄ (i.e. up to 50 µ M ), indicating that copper was not toxic to the cells at that high concentrations. Cu-adapted cell suspensions grew faster than the control in limiting light conditions and had higher content of chlorophyll per dry weight of cells. Copper was accumulated within the cells, and this event was accompanied by (1) increased oxygen evolution activity; (2) increased number of chloroplasts per cell, smaller chloroplasts, increased thylakoid stacking and grana size; (3) higher fluorescence emission of photosystem II antenna complexes and (4) stimulation of plastocyanin protein synthesis compared with untreated cells. Microanalysis of cross-sections revealed an increase of copper content in chloroplasts as well as vacuole, cytoplasm and cell wall in Cu-adapted cells. No antagonist interaction between copper and iron uptake took place in these cell suspensions. On the other hand, copper at subtoxic concentrations stimulated oxygen evolution activity in thylakoids from control cells, but this event did not take place in those from Cu-adapted ones. Furthermore, the loss of activity by copper inhibitory action at toxic concentrations was two-fold slower in thylakoids from Cu-adapted cells compared with the control ones. The data strongly indicate that copper plays a specific positive role on photosynthesis and stimulates the growth and the oxygen evolution activity in soybean cell suspensions.     

Effects of copper on mammalian cell components

Both deficiency and excess of copper induce toxic effects on mammalian cell systems in vivo and in vitro. The effects can be related to the affinities of Cu(II) ions for specific cell components. The nucleus is a potential site for temporary Cu storage while primary targets for free Cu(II) ions are the thiol groups which reduce the ions to Cu(I). Cu(II) ions show a high affinity for nucleic acids, binding with DNA both at intrastrand and interstrand levels, possibly through intercalation between GC pairs. The ability to chelate Cu(II) ions is seen to be of the order: purine greater than purine ribonucleotides greater than purine ribonucleoside greater than pyrimidine ribonucleotides. Copper is an integral part of enzyme activation and enters into the molecular structure of several proteins, like ceruloplasmin. Cu(II) ion is a potential mutagenic agent as seen by its property of inducing infidelity in DNA synthesis in vitro. Teratogenic activities of copper have been reported but carcinogenicity is not yet confirmed. Copper is an essential component of chromatin and is known to accumulate preferentially in the heterochromatic regions. External application of higher doses, however, induces both clastogenic effects and spindle disturbances. In certain forms, inorganic copper enhances the clastogenic activity of other agents. The most widely studied human genetic maladies linked with copper metabolism are Menkes' and Wilson's diseases. Several mutations are known which influence Cu homeostasis in mammals. Such mutations in mice have been used extensively for biochemical studies.