Anaerobically induced production of hybrid monokaryons by heterokaryons of Candida albicans

Summary During aerobic replication, balanced heterokaryons (hets) of Candida albicans produced by fusing protoplasts of complementing auxotrophic strains characteristically segregate low frequencies of prototrophic monokaryons bearing hybrid nuclei formed either through karyogamy or unidirectional internuclear genetic transfers within het cells. Anaerobic growth causes exponential inactivation of hets and induces their production of hybrid monokaryons. Both responses are functions of heterokaryosis as such and not the genetic backgrounds of hets. Evidence is presented that (i) the nuclei of anaerobically generated hybrids arise through induction in hets of karyogamy not internuclear genetic transfers and that (ii) the events underlying that induction are different from those responsible for inactivation of the cells.     

Effects of growth temperatures on plating efficiencies and stabilities of heterokaryons of Candida albicans

Heterokaryons (hets) of Candida albicans constructed by fusing protoplasts of complementing auxotrophs produce heterogeneous clones on minimal medium consisting of (i) a minority of slow-growing hets, (ii) a preponderance of non-growing, parental-type auxotrophic monokaryons, and (iii) some prototrophic monokaryons bearing hybrid nuclei. Hets grown at a given temperature within the range 25° C to 41° C replate with higher efficiencies at any lower temperature and exhibit progressively declining plating efficiencies as plate temperatures increase beyond that at which they were initially grown. Neither auxotrophic nor prototrophic monokaryons show such responses. Growth of colonies produced by hets, wild-type strains or prototrophic hybrid monokaryons is stimulated by temperatures in the order, 37° C > 30° C > 41° C > 25° C. However, the proportion of hets to auxotrophic monokaryons within individual net clones increases directly from 25° C to 41° C. Though this pattern obtains whether colonies are compared at equivalent sizes or ages, het frequencies decline as colonies age at all temperatures. Appearance of hybrid monokaryons within het clones is unaffected by growth temperature. The relationships of temperatures to plating efficiencies and stabilities of hets are independent of the natures of their complementing auxotrophies or the wild-type backgrounds of their nuclear components and are, therefore, functions of heterokaryosis per se. Modifications of these relationships by selective metabolic antagonists or by growth of hets on different preand post-plating carbon sources indicate that they reflect temperature-dependent properties of mitochondria which are peculiar to hets.     

Reactivation of chick erythrocyte nuclei in heterokaryons with temperature-sensitive Chinese hamster cells.

Chinese hamster cell line K12 is temperature-sensitive for the initiation of DNA synthesis. K12 cells synchronized by serum deprivation were collected in early G1(G0). Heterokaryons were formed by fusing chick erythrocytes with serum-starved K12 cells through the use of UV-irradiated Sendai virus. At the permissive temperature (36.5 degrees C), erythrocyte nuclei in heterokaryons enlarged, the chromatin dispersed, and erythrocyte nuclei synthesized DNA at about the same time as the K12 nuclei. At the restrictive temperature (41 degrees C), erythrocyte nuclei enlarged, but neither erythrocyte nor K12 nuclei initiated DNA synthesis. When erythrocyte nuclei were fused with Wg-1A cells, the wild-type parent for ts K12 cells, both kinds of nuclei synthesized DNA at 36.5 degrees C and 41 degrees C. Activation of erythrocyte nuclei was inefficient in heterokaryons incubated in low-serum medium. The results indicate that serum factors and a cellular function defined by the K12 mutation are required for activation of chick erythrocyte nuclear DNA synthesis.     

Natural heterozygosity in Candida albicans.

We subjected 16 Candida albicans clinical isolates to ultraviolet radiation and tested the survivors for auxotrophy. Six isolates displayed strongly biased auxotroph spectra: three yielded methionine auxotrophs, two yielded both isoleucine-valine and adenine auxotrophs, and one yielded lysine auxotrophs. We present evidence that auxotrophs arise by segregation from naturally occurring heterozygous states. The remaining isolates yielded few or no auxotrophs in an arbitrary sample (greater than 2,500) of survivors of irradiation. Our experiments indicate that C. albicans is diploid, although aneuploidy (2n + i) cannot be rigorously excluded. We discuss the possible utility of heterozygosity as a marker in epidemiological studies, and we discuss a rationale for the frequent occurrence of heterozygosity.     

Protein synthesis kinetics with ribosomes from temperature-sensitive mutants of Escherichia coli.

The kinetics of MS2 ribonucleic acid (RNA) directed protein synthesis have been investigated at seven temperatures between 30 and 47 degrees C by using ribosomes isolated from a wild type strain and seven temperature-sensitive mutants of Escherichia coli. The amount of MS2 coat protein formed at each temperature was determined by gel electrophoresis of the products formed with control ribosomes. With ribosomes from each of the mutant strains, the activation energy required to drive protein synthesis below the maximum temperature (up to 40 degrees C) was increased relative to the control (wild type) activity. Preincubation of the ribosomes at 44 degrees C revealed the kinetics of thermal inactivation, with ribosomes from each of the mutants having a half-life for inactivation less than that of the control ribosomes. A good correlation was observed between the relative activity of the different ribosomes at 44 degrees C and their relative rate of thermal inactivation. Mixing assays allowed the identification of a temperature-sensitive ribosomal subunit for each of the mutants. Defects in one or more of three specific steps in protein synthesis (messenger RNA binding, transfer RNA binding, transfer RNA binding, and subunit reassociation) were identified for the ribosomes from each mutant. The relationship between temperature sensitivity and protein synthesis in these strains is discussed.     

DNA synthesis in isolated resting nuclei: evidence for protease-dependent nonreplicative nucleotide incorporation.

We have used an in vitro assay to study the induction of DNA synthesis by cytoplasmic extracts from the actively growing cell line Molt 4 in nuclei isolated from quiescent human lymphocytes. The TTP incorporation which takes place in these nuclei has been shown to be inhibitable by serine protease inhibitors, particularly aprotinin. This DNA synthesis has also been proposed to reflect the initiation of true DNA replication; however, we find evidence that much, if not most, of this incorporation is due to nonreplicative synthesis initiated on primer templates formed by calcium-dependent activation of the nuclear chromatin substrate. The principal DNA polymerase supplied by the Molt 4 extract appears to be polymerase alpha and the results show that the activated chromatin is a substrate for purified bacterial DNA polymerases. DNA synthesis is significantly enhanced by preincubation at 37 degrees C in the presence of calcium, and the almost complete inhibition of DNA synthesis induced by extracts or bacterial polymerases in the presence of T4 ligase suggests that this chromatin activation involves calcium-dependent endonucleases. Nevertheless, DNA synthesis in the isolated nuclei, with both Molt 4 extracts and bacterial polymerases, is substantially inhibited by addition of serine protease inhibitors, with aprotinin the most potent of those tested on a molar basis. Thus, the results suggest that specific proteolytic activity is required before nicked or damaged nuclear DNA can serve as an acceptable substrate for DNA polymerase activity.     

Recombinogenic activity of nalidixic acid for artificial hybrids but not for natural strains of Candida albicans: evidence for the monoploidy of natural strains

Nalidixic acid induces segregation of auxotrophs from prototrophic hybrids of Candida albicans artifically produced by fusing complementing auxotrophic protoplasts. The auxotrophies recovered are limited to those introduced through the fusion process, and patterns of segregations for linked auxotrophic markers demonstrate the segregants are products mitotic crossing-over. Nalidixic acid does not induce auxotrophies of any sort in clinical isolates of C. albicans. These findings are contrary to a current hypothesis that natural strains of C. albicans are diploid and heterozygous for a variety of auxotrophic mutations.     

Transmission and expression of mutations to nalidixic acid resistance among products of protoplast fusion crosses of Candida albicans

Earlier studies suggested that heritable resistance to nalidixic acid (Nal) induced in the asexual, pathogenic yeast Candida albicans by growth on Nal results from mitochondrial mutation. To determine conclusively whether mutations to Nal resistance are cytoplasmic or nuclear, several stable Nal-resistant (Nalr) mutants exhibiting distinctive differences in degrees of Nal resistance were obtained from each of two doubly auxotrophic strains (Ade-, Thr- and Arg-, His-), both derived from the same wild-type stock. Inheritance of Nal resistance was then assessed in a series of protoplast fusion crosses between complementing auxotrophs. The initial, intact cellular products of a fusion cross are prototrophic heterokaryons which frequently assort single parental nuclei into monokaryotic blastospores containing biparental cytoplasms. Occasional karyogamy within heterokaryons also yields prototrophic hybrid monokaryons which can undergo recombinations for chromosomal markers through spontaneous or induced mitotic crossing-over. Segregation and expression of Nal resistance among non-hybrid, parental-type monokaryons from Nalr X Nals heterokaryons showed that Nalr mutations are nuclear and that their expressions are not noticeably affected by admixture of cytoplasms of sensitive and resistant parental strains. Analyses of heterokaryons and hybrid monokaryons from Nalr X Nals and Nalr X Nalr crosses demonstrated that Nal resistance is recessive to sensitivity, and that independent Nalr mutations arise at one gene in the Ade-, Thr- strain and at a separate, complementing single gene in the Arg-, His- strain. Prior work demonstrated that induction of Nalr mutations in wild-type C. albicans depends profoundly on the (i) carbon and nitrogen, (ii) growth temperature, (iii) contact with particular metabolic inhibitors and (iv) division stage of cells during exposure to Nal. The present observations indicate that the character of cellular auxotrophies can determine the genetic loci at which Nalr mutations can be recovered.     

The relationship between DNA strand-scission and DNA synthesis inhibition in HeLa cells treated with neocarzinostatin.

Neocarzinostatin inhibits DNA synthesis in HeLa S3 cells and induces the rapid limited breakage of cellular DNA. The fragmentation of cellular DNA appears to precede the inhibition of DNA synthesis. Cells treated with drug at 37 degrees C for 10 min and then washed free of drug show similar levels of inhibition of DNA synthesis or cell growth, or of strand-scission of DNA as when cells were not washed. If cells are preincubated with neocarzinostatin at 0 degrees C before washing, the subsequent incubation of 37 degrees C results in no inhibition of DNA synthesis or cell growth, or cutting of DNA. Isolated nuclei or cell lysates derived from neocarzinostatin-treated HeLa S3 cells are inhibited in DNA synthesis but this can be overcome in cell lysates by adding activated DNA. A cytoplasmic fraction from drug-treated cells can stimulate DNA synthesis by nuclei isolated from untreated cells, whereas nuclei from drug-treated cells are not stimulated by the cytoplasmic fraction from untreated cells. By contrast, neocarzinostatin does not inhibit DNA synthesis when incubated with isolated nuclei, but it can be shown that under these conditions the DNA is already degraded and is not further fragmented by the drug. These data suggest that the drug's ability to induce breakage of cellular DNA in HeLa S3 cells is an essential aspect of its inhibition of DNA replication and may be responsible for the cytotoxic and growth-inhibiting actions of neocarzinostatin.     

Interspecific complementation analysis by protoplast fusion of Candida tropicalis and Candida albicans adenine auxotrophs.

A protocol employing inositol starvation was used to isolate proline and adenine auxotrophs of Candida tropicalis. Interspecific hybrids between red adenine auxotrophs of C. tropicalis and Candida albicans were formed by protoplast fusion. These C. tropicalis red adenine auxotrophs were shown to fall into two complementation groups by crossing them with a known C. albicans ade1 tester strain. It is suggested that these two groups correspond to the ade1 and ade2 mutants of Saccharomyces cerevisiae and C. albicans and that these defined mutants may be useful in attempts to develop transformation systems for C. tropicalis.     

Mitochondrial protein synthesis in a mammalian cell-line with a temperature-sensitive leucyl-tRNA synthetase.

The temperature-sensitive Chinese hamster ovary cell mutant tsH1, has been shown previously to contain a temperature-sensitive leucyl-tRNA synthetase. At the non-permissive temperature of 40 degrees C cytosolic protein synthesis is rapidly inhibited. The protein synthesis which continues at 40 degrees C appears to be mitochondrial, since: (a) whole-cell protein synthesis at the permissive temperature of 34 degrees C is not inhibied by tevenel, the sulfamoyl analogue of chloramphenicol and a specific inhibitor of mitochondrial protein synthesis; however, whole-cell protein synthesis at 40 degrees C is inhibited by tevenel, (b) Protein synthesis by isolated mitochondria from tsH1 cells is not significantly inhibited at 40 degrees C. (c) At 40 degrees C [14C]leucine is incorporated predominantly into the mitochondrial fraction of tsH1 cells. (d) The incorporation of [14C]leucine at 40 degrees C into mitochondrial proteins of tsH1 cells is inh-bited by tevenel but not by cycloheximide. These results suggest that the mitochondria of tsH1 cells contain a leucyl-tRNA synthetase which is different from the cytosolic enzyme. The inhibition of cytosolic, but not of mitochondrial protein synthesis in tsH1 cells at 40 degrees C allows the selective labelling of mitochondrial translation products in the absence of inhibitors. The mitochondrial translation products labelled in tsH1 cells at 40 degrees C and at 34 degrees C in the presence of cycloheximide have been compared by sodium dodecylsulphate-polyacrylamide gel electrophoresis. Both conditions of labelling give similar profiles. The mitochondrial translation products are resolved into two components, one with an apparent molecular weight range from 40,000 to 20,000 and a second with an apparent molecular weight range from 20,000 to 10,000.     

Characterization of DNA synthesis and DNA-dependent ATPase activity at a restrictive temperature in temperature-sensitive tsFT848 cells with thermolabile DNA helicase B.

A temperature-sensitive mutant defective in DNA replication, tsFT848, was isolated from the mouse mammary carcinoma cell line FM3A. In mutant cells, the DNA-dependent ATPase activity of DNA helicase B, which is a major DNA-dependent ATPase in wild-type cells, decreased at the nonpermissive temperature of 39 degrees C. DNA synthesis in tsFT848 cells at the nonpermissive temperature was analyzed in detail. DNA synthesis measured by incorporation of [3H]thymidine decreased to about 50% and less than 10% of the initial level at 8 and 12 h, respectively. The decrease in the level of thymidine incorporation correlated with a decrease in the number of silver grains in individual nuclei but not with the number of cells with labeled nuclei. DNA fiber autoradiography revealed that the DNA chain elongation rate did not decrease even after an incubation for 10 h at 39 degrees C, suggesting that initiation of DNA replication at the origin of replicons is impaired in the mutant cells. The decrease in DNA-synthesizing ability coincided with a decrease in the level of the DNA-dependent ATPase activity of DNA helicase B. Partially purified DNA helicase B from tsFT848 cells was more heat sensitive than that from wild-type cells. Inactivation of DNA-dependent ATPase activity of DNA helicase B from mutant cells was considerably reduced by adding DNA to the medium used for preincubation, indicating that the DNA helicase of mutant cells is stabilized by binding to DNA.     

Disruption of mitochondrial function in<Emphasis Type="Italic"> Candida albicans</Emphasis> leads to reduced cellular ergosterol levels and elevated growth in the presence of amphotericin B

A respiratory-deficient mutant of Candida albicans MEN was generated by culturing cells in medium supplemented with ethidium bromide at 37 degrees C for 5 days. The respiratory-deficient mutant (C. albicans MMU11) was incapable of growth on glycerol, had a reduced oxygen uptake rate and demonstrated an altered mitochondrial cytochrome profile. Respiratory-competent cybrids were formed by mitochondrial transfer following fusion of protoplasts with those of C. albicans ATCC 44990. Mutant MMU11 possessed lower levels of ergosterol than the parental isolates and the cybrids, and demonstrated a small but statistically significant increase in tolerance to amphotericin B. The results demonstrated that disruption of mitochondrial function in C. albicans increases the tolerance to amphotericin B, possibly mediated by a reduction in cellular ergosterol content.     

Cell death in Escherichia coli dnaE(Ts) mutants incubated at a nonpermissive temperature is prevented by mutation in the cydA gene

Cells of the Escherichia coli dnaE(Ts) dnaE74 and dnaE486 mutants die after 4 h of incubation at 40 degrees C in Luria-Bertani medium. Cell death is preceded by elongation, is inhibited by chloramphenicol, tetracycline, or rifampin, and is dependent on cell density. Cells survive at 40 degrees C when they are incubated at a high population density or at a low density in conditioned medium, but they die when the medium is supplemented with glucose and amino acids. Deletion of recA or sulA has no effect. We isolated suppressors which survived for long periods at 40 degrees C but did not form colonies. The suppressors protected against hydroxyurea-induced killing. Sequence and complementation analysis indicated that suppression was due to mutation in the cydA gene. The DNA content of dnaE mutants increased about eightfold in 4 h at 40 degrees C, as did the DNA content of the suppressed strains. The amount of plasmid pBR322 in a dnaE74 strain increased about fourfold, as measured on gels, and the electrophoretic pattern appeared to be normal even though the viability of the parent cells decreased 2 logs. Transformation activity also increased. 4',6'-diamidino-2-phenylindole staining demonstrated that there were nucleoids distributed throughout the dnaE filaments formed at 40 degrees C, indicating that there was segregation of the newly formed DNA. We concluded that the DNA synthesized was physiologically competent, particularly since the number of viable cells of the suppressed strain increased during the first few hours of incubation. These observations support the view that E. coli senses the rate of DNA synthesis and inhibits septation when the rate of DNA synthesis falls below a critical level relative to the level of RNA and protein synthesis.     

Cycloheximide and heat shock induce new polypeptide synthesis in Neurospora crassa.

Treatment of Neurospora crassa with 0.1 microgram of cycloheximide per ml, a concentration which inhibited protein synthesis by about 70%, resulted in the greatly enhanced synthesis of at least three polypeptide bands with estimated molecular weights of 88,000, 30,000, and 28,000. A temperature shift from 25 to 37 degrees C resulted in the appearance of a single new polypeptide band of 70,000 daltons, the same size as the major heat shock-induced proteins observed in species of Drosophila and Dictyostelium. Synthesis of the cycloheximide-stimulated polypeptide bands was on cytoplasmic ribosomes rather than on mitochondrial ribosomes, as incorporation of isotope into the polypeptide bands was inhibited by 1.0 microgram of cycloheximide per ml but not by 1 mg of chloramphenicol per ml. In a mutant with cycloheximide-resistant ribosomes, 0.1 microgram of cycloheximide per ml failed to alter the pattern of protein synthesis from that of the controls. It is suggested that the new synthesis of the polypeptide bands reflects specific mechanisms of adaptation to different kinds of environmental stress, including inhibition of protein synthesis and temperature increases.     

Translational regulation of the synthesis of a major heat shock protein in HeLa cells

The synthesis of a major heat shock protein (HSP 70) was measured in HeLa cells incubated at 42.5 degrees C and then transferred to 37 degrees C or 30 degrees C. After 90 min, synthesis of HSP 70 decreased by 54 and 85%, respectively, whereas HSP 70 mRNA was reduced at most by 20%. Therefore, the reduced synthesis of HSP 70 could not be accounted for by mRNA turnover. HSP 70 was associated with large polyribosomes (6-10 ribosomes) in cells kept at 42.5 degrees C, but with medium or small polyribosomes in cells transferred to 37 degrees C or 30 degrees C (5-6 or 2-3 ribosomes, respectively). Addition of puromycin to these cells resulted in the release of all ribosomes from HSP 70 mRNA, indicating that they were translationally active. The regulation of HSP 70 synthesis was investigated in cell-free systems prepared from heat-shocked or control cells and incubated at 30 degrees C and 42 degrees C. After 5 min at 42 degrees C, the cell-free system from heat-shocked cells synthesized protein at 3 times the rate of the control cell-free system. This difference was in large part due to synthesis of HSP 70. Addition of HSP mRNA to the control cell-free system stimulated protein synthesis at 42 degrees C, but not at 30 degrees C. These findings suggest that translation of HSP 70 mRNA is specifically promoted at high temperature and repressed during recovery from heat shock by regulatory mechanisms active at the level of initiation.     

Bacteriolytic activity of seminalplasmin

Seminalplasmin, an antimicrobial protein from bovine seminal plasma, lysed both Gram-positive and Gram-negative bacteria but not Candida albicans. The lytic activity was not lysozyme-like and was not affected by inhibitors of RNA or protein synthesis or by azide; it was strongly inhibited by divalent cations like Ca2+, Mn2+ and Mg2+ at millimolar concentrations. Maximum lysis of Escherichia coli was obtained at 37 degrees C; heat treatment of E. coli drastically reduced its susceptibility to lysis by seminalplasmin. E. coli cells in the stationary phase of growth were lysed much less than those in the exponential phase, and those grown in an enriched medium were lysed much more than those grown in a minimal medium. It appears that the lytic activity of seminalplasmin is due to the activation of an autolysin.     

Proteolysis of products of mitochondrial protein synthesis in isolated mitochondria of Saccharomyces cerevisiae yeasts]

Products of mitochondrial protein synthesis were specifically labeled with 3H-leucine in the presence of cycloheximide at the end of the exponential phase of yeast aerobic growth on glucose. The mitochondria isolated from these cells lost 37-40% of the label from the protein fraction during 60 min incubation at 35 degrees, which was accompanied by the accumulation of 3H-leucine in TCA-soluble fraction. This process was suppressed by phenyl-methyl sulfonyl fluoride and p-chloromercuriphenyl sulfonate, the inhibitors of proteases, and could thus be considered as the proteolysis of the products of mitochondrial protein synthesis. The proteolysis was ATP dependent and was stimulated by puromycine which is known to induce the removal of incomplete polypeptides from mitochondrial ribosomes. A body of indirect evidence allows a suggestion to be made that the observed proteolysis can hardly be due to the action of cytoplasmic proteinases.