Thioltransferase overexpression increases resistance of MCF-7 cells to adriamycin.

Thioltransferase, a small redox protein with thiol-disulfide oxidoreductase and dehydroascorbate reductase activities, has been reported to be expressed at higher levels in Adriamycin-resistant MCF-7 human breast tumor cells (MCF-7 ADR(R)) when compared with Adriamycin sensitive MCF-7 WT (MCF-7 WT) cells. The present study examined the effects of stably transfecting MCF-7 WT cells with the cDNA for human thioltransferase and the effects of subsequent Adriamycin cytotoxicity in the MCF-7 WT transfected cells. All transfected cell lines overexpressing thioltransferase activity were more resistant to Adriamycin than untransfected MCF-7 WT cells, supporting the hypothesis that increases in thioltransferase expression are related to Adriamycin resistance. This resistance was independent of the ability of thioltransferase to catalyze reduction of dehydroascorbic acid to ascorbic acid, as the addition of an ascorbate generating derivative, L-ascorbic acid-2-phosphate, to the media did not additionally increase Adriamycin resistance.

Ascorbic acid and cell survival of adriamycin resistant and sensitive MCF-7 breast tumor cells.

The ability of human cells to regenerate ascorbic acid from dehydroascorbate is partially dependent on the glutathione redox status of the cell and the relative activity of dehydroascorbate reductases. Mammalian dehydroascorbate reductase activity is associated with two proteins known as thioltransferase (glutaredoxin) and protein disulfide isomerase. We compared the specific activity of thioltransferase, protein disulfide isomerase, and other GSH-related enzymes in Adriamycin-resistant human breast tumor cells, MCF-7 ADRR, and Adriamycin-sensitive, MCF-7 WT, tumor cells. MCF-7 ADRR cells had higher activities of glutathione peroxidase (34.7 fold), nonseleno-glutathione peroxidase (glutathione S-transferases; 5.3 fold), thioredoxin (2.3 fold), and thioltransferase (4.0 fold) compared with the WT Adriamycin-sensitive cell line. Thioltransferase was detected in Western blots in extracts of ADRR MCF-7 cells but not in WT MCF-7 cells. alpha-Tocopherol in the membrane and cytosolic fractions was 2.8 and 3.0 fold higher, respectively, in Adriamycin-resistant compared with Adriamycin-sensitive cells. Supplementation of MCF-7 cells with L-ascorbic acid 2-phosphate (2 and 10 mM) had no effect on WT cell viability after 5 days incubation with up to 0.33 microM Adriamycin. In contrast, supplementation of ADRR MCF-7 cells with L-ascorbic acid 2-phosphate resulted in enhanced resistance up to 3.4 microM Adriamycin over a 5-day incubation. Both lines of MCF-7 cells demonstrated the ability to utilize ascorbic acid as the 2-phosphate derivative. After 48 h incubation with 8.6 microM Adriamycin, the resistant cells maintained normal viability and ascorbate-dehydroascorbate levels, whereas drug-sensitive cells had significantly lower ascorbate with a higher percent dehydroascorbate and increased cell death as judged by cell protein levels (52% of controls).

Crypthecodinium and Tetrahymena: an exercise in comparative evolution.

Nucleotide sequences have been determined for the highly variable D2 region of the large rRNA molecule for over 60 strains of dinoflagellates. These strains were selected from a worldwide collection that represents all the known sibling species (compatibility groups, Mendelian species) in the sibling swarm referred to as Crypthecodinium cohnii. A phylogenetic tree has been constructed from an analysis of the variations in a length of about 180 bases, using PHYLOGEN string analysis programs. The Crypthecodinium tree is compared with the previously published but here augmented tree constructed upon the same rRNA region for the sibling species of a worldwide collection of ciliated protozoa related to the genus Tetrahymena. The first reported sequence of Lambornella clarki, the parasite of tree-hole mosquitoes, is included. The dinoflagellate species complex is much more homogeneous with respect to ribosomal variation. The mean number of differences among sequences from different Crypthecodinium species is about 7, in comparison with 22 differences among the ciliate species examined. Moreover, all the diversity in the dinoflagellates can be explained by base substitutions, whereas insertions and deletions are common in the ciliates. The dinoflagellates are also much more uniform with respect to nutritional and genetic economies. The two complexes differ also in the relationship between molecular variations and breeding compatibility. All tetrahymenine sibling species thus far examined are monomorphic in the D2 region, but several dinoflagellate species are polymorphic. Several different dinoflagellate species, moreover, have identical D2 regions. This kind of ribosomal identity of incompatible strains is found in these ciliates only in one tight cluster of species--Group C. The tetrahymenine swarm is apparently much older than the Crypthecodinium swarm, and the dinoflagellate species produce incompatible progeny species much more readily than do the ciliates, perhaps by the acquisition of mutations that potentiate incompatibility in sympatric populations.

Suicide is not the inevitable outcome of "perpetual" selfing in tetrahymenines collected from natural habitats.

A significant fraction of the Tetrahymena clones isolated from natural habitats self (mating occurs within a clone). Early attempts to study such clones failed because stable subclones were rarely, if ever, observed, and isolated pairs all died. Isozyme analysis revealed that these wild selfers were a diverse group; some were very similar to T. australis, a species with synclonal mating type determination and to T. elliotti, shown recently to have a karyonidal mating type system. One originally stable clone of T. australis included some selfing clones after a few years in our laboratory. Other clones manifested unique zymograms. Subclones isolated from 18 selfer strains were heterogeneous. All subclones of several selfers mated massively at each transfer through 100 fissions. Selfing among subclones of other selfers was highly variable or not observed. Although 77% of the pairs isolated died, and 9% of the pair cultures selfed, 15 selfers yielded some viable nonselfing "immature" progeny. Additional immature progeny were obtained by isolating pairs from macronuclear retention synclones. Although some "immature" progeny eventually selfed, most remained stable. Giemsa staining revealed macronuclear anlagen in nearly all mating pairs and some anomalies. Crosses among the F1 progeny clones of the T. elliotti selfers yield viability data comparable to those from crosses among normal strains. Perhaps perpetual selfing is a mechanism of getting rid of deleterious combinations of genes and uncovering better combinations in homozygous state by playing genetic roulette.

Eukaryotic origins: string analysis of 5S ribosomal RNA sequences from some relevant organisms.

Using the PHYLOGEN tree-forming programs, we evaluate the published 5S rRNA sequences in certain of the files in the Berlin DataBank in an attempt to identify the connection between archaebacteria and the eukaryotic protists. These programs are based on methods of string analysis developed by Sankoff and others. Their discriminatory power is derived from their continuous realignment of sequences through repeated assessment of insertions and deletions as well as substitutions. The programs demonstrate that even these small molecules (ca. 120 bases) retain substantial records of evolutionary events that occurred over a billion years ago. The eukaryotes seem to have been derived from ancestors near the common origins of the halobacterial and Methanococcales groups. Identifying what might have been a primordial eukaryote is more difficult because several of the species considered as early derivatives from the common root are isolated species with large genetic differences from each other and from all other extant forms that have been sequenced. The ameboid, flagellated, and ciliated protists seem to have emerged nearly simultaneously from an ancient cluster, but the sarcodinid protozoa have preference as the group of most ancient origin. The euglenozoa and the ciliates are of later derivation. Our ability to tease plausible trees from such small molecules suggests that the mode of analysis rather than the size of the molecule is often a major limitation in the reconstruction of acceptable ancient phylogenics.(ABSTRACT TRUNCATED AT 250 WORDS)

Ciliate evolution: the ribosomal phylogenies of the tetrahymenine ciliates.

We have assembled and analyzed nucleotide sequences for several different rRNA components from tetrahymenine ciliates. These include previously published and some new 5S and 5.8S rRNAs for a total of 18 species. We also report sequences for some 30 species obtained by primer extension analysis of a region near the 5' end of the 23S rRNAs (region 580). Phylogenetic trees have been constructed for these species, utilizing heuristics (shifting ditypic site analysis) described in a companion paper. The trees based on these sequences are consistent with each other and with those based on longer sequences of the 17S rRNA. They show the tetrahymenines to consist of a number of distinctive clusters of species. The clusters (ribosets) are homogeneous with respect to certain life history characteristics, especially the mode of mating type determination, but are inhomogeneous with respect to some morphological and life history features, such as cyst formation and adaptations to parasitism or carnivory. Using the same molecular data, we also begin to explore the relationships of the tetrahymenines to some other ciliate taxa and to some other protists.

Shifting ditypic site analysis: heuristics for expanding the phylogenetic range of nucleotide sequences in Sankoff analyses.

We describe and illustrate a simple heuristic approach to the Sankoff methods for construction of parsimonious evolutionary trees from nucleotide sequence data. The procedure is intended to permit more valid inferences, particularly from relatively short sequences, concerning relationships among taxa separated for long time intervals. The procedure is based on the great variability of evolutionary plasticity among sites in the molecules and removes from consideration the more highly variable sites. Editing is accomplished after classifying sites in carefully aligned arrays of sequences. Only "ditypic sites," i.e., sites observed in only two evolutionary states within the array, are used in making phylogenetic inferences. This strategy makes possible the construction of good approximations to the most parsimonious Steiner trees, by means of efficient programs that require "dense species arrays," i.e., species sets that differ from each other by relatively small numbers of differences in conservative sites. The technique is illustrated with 5S and 5.8S rRNA sequence data from published catalogs.

Comparison of ribosomal and isozymic phylogenies of tetrahymenine ciliates.

A recent analysis of sequence variations in ribosomal RNA's from 31 species of tetrahymenine ciliates groups them into 9 sets referred to as "ribosets." These species associations are not well correlated with the distributions of distinctive morphological characteristics. The phylogenetic structure suggests that modern "pyriform" tetrahymenines may be paraphyletic survivors of primitive design and that the morphologically distinctive forms may include examples of convergent evolution of derived forms. Alternatively, the common ancestor may have been a polymorphic species that has lost its plasticity in some derived lineages. In an attempt to test the ribosomal phylogeny, we here compare it with a phylogeny based on isozymic variation. The main features of the ribosomal and isozymic phylogenies are similar. The carnivorous (macrostome-forming) species are widely scattered in both, as are the bacteriophagous pyriform species. Isozymic and ribosomal analyses are optimally useful, however, in different contexts. Isozymic variations can distinguish species that are ribosomally identical. Ribosomal variations provide more secure evaluations of distant relationships.

New wild Tetrahymena from Southeast Asia, China, and North America, including T. malaccensis, T. asiatica, T. nanneyi, T. caudata, and T. silvana n. spp.

Tetrahymena of the T. pyriformis complex collected from varied habitats in Malaysia, Thailand, and The People's Republic of China include strains of the micronucleate species T. americanis and T. canadensis and the amicronucleate T. pyriformis and T. elliotti. Two new breeding species are described-T. malaccensis from Malaysia and T. asiatica from China and Thailand. Two wild selfers from China and some of the amicronucleate strains from all three countries fall into isozymic groups similar to named micronucleate and amicronucleate species. The T. patula complex is represented by two groups of clones from Malaysia that fit the morphological description of T. vorax. They, however, have radically different isozymic electrophoretic patterns and both groups differ from those of previously described T. vorax. As their molecules indicate relationships to other "T. vorax" strains as distant as that between T. vorax and T. leucophrys, they are considered to be new species, T. caudata and T. silvana. A third new breeding species, T. nanneyi, was identified among strains previously collected in North America. Viable immature progeny were obtained from the new strains of the five breeding species. Maximum temperature tolerances were determined for the new strains of four of the breeding species.

Perturbance analysis of nuclear determination in Tetrahymena: effects of nutrition, cell extracts, and CaCl2 on A/B hybrids.

Mating type frequencies were ascertained among the progeny of crosses of strains A x B, Tetrahymena thermophila under a number of different circumstances. The frequencies are different if the parents are severely starved than if they are well-fed at the time of conjugation; severe starvation of the progeny before the first post-zygotic division has an effect similar to that of starving the parents. Mating type frequencies may also be modified by isolating conjugating pairs into cell extracts before the new macronuclei begin to develop; the changes do not appear to be related in a meaningful way to the mating type of the cells used as a source of the cell extracts. A third means of changing the mating type frequencies involves the exposure of conjugating pairs to CaCl2 solutions. Finally, changed frequency patterns may appear "spontaneously", and reflect either some as yet unsuspected environmental variable, or else an intrinsic metastable state that conditions the probabilities of mating type fixation. With the exception of the starvation effects, the pattern variations seem to fall into two groups. No satisfactory mechanism to account for these results is yet available.

Scalar constraints in Tetrahymena evolution. Quantitative basal body variations within and between species.

Tetrahymenas of 17 species of the T. pyriformis complex have been stained with protargol and analyzed for numbers of basal bodies in half cells just before cell division. At this stage, cells of all strains manifest considerable variation in numbers of basal bodies; the coefficient of variation (sigma/m) is usually between 0.05 and 0.10. Much of this variability is observed in cells in the same nutritional state, at the same stage of the growth cycle, and in the same part of the life cycle. The basal body variability may be related to the variation in macronuclear DNA content that results from the imprecise amitotic macronuclear division. With a few exceptions, strains of different species are difficult to distinguish on the basis of basal body numbers. The species means in the samples examined show a range only from 234 (T. furgasoni) to 481 (T. capricornis), about a twofold difference. This limited variation in the means suggests that these organisms are constrained within narrow limited by some scalar function of their organismic design, which prevents an evolutionary size dispersion--even though molecular scrambling has occurred in the complex at an appreciable rate for a very long evolutionary interval.

Perturbance analysis of nuclear determination in Tetrahymena I: background, rationale, and illustrative example, employing temperature responses.

A model based on comparative considerations, is presented for the nuclear determination of mating type in Tetrahymena thermophila. The model proposes a system of three binary control elements, each capable of stable persistence in one of two states. A general method is proposed for evaluating the model and for assigning particular mating types to particular compound states. Preliminary assignments of mating types are made from the responses of nuclei to temperature differentials.

Traumatic induction of early maturity in tetrahymena.

Exposure of conjugating pairs of Tetrahymena thermophila to high temperature (37 degrees) during macronuclear development causes an abortion of many macronuclei, but it also often induces an early appearance of sexual maturity in clones completing macronuclear development. Lines become mature after about 15 cell divisions rather than after 50 or more cell divisions in untreated pairs. The phenotype resembles that associated with Em (early maturity) mutants but, because it is not transmitted to the progeny in the next generation, it must be considered a phenocopy. The hypothesis is developed that an early genotype-environment incompatibiltiy, whether associated with an abnormal genotype or an unusual environment, activates a shunt mechanism permitting the organisms to undertake quickly an ordinarily forbidden sexual lottery.