An improved microinjection technique in Paramecium aurelia. Transfer of mitochondria conferring erythromycin-resistance

Mitochondria in the Central Nervous System in Health and Disease: The Puzzle of the Therapeutic Potential of Mitochondrial Transplantation

Mitochondria, the energy suppliers of the cells, play a central role in a variety of cellular processes essential for survival or leading to cell death. Consequently, mitochondrial dysfunction is implicated in numerous general and CNS disorders. The clinical manifestations of mitochondrial dysfunction include metabolic disorders, dysfunction of the immune system, tumorigenesis, and neuronal and behavioral abnormalities. In this review, we focus on the mitochondrial role in the CNS, which has unique characteristics and is therefore highly dependent on the mitochondria. First, we review the role of mitochondria in neuronal development, synaptogenesis, plasticity, and behavior as well as their adaptation to the intricate connections between the different cell types in the brain. Then, we review the sparse knowledge of the mechanisms of exogenous mitochondrial uptake and describe attempts to determine their half-life and transplantation long-term effects on neuronal sprouting, cellular proteome, and behavior. We further discuss the potential of mitochondrial transplantation to serve as a tool to study the causal link between mitochondria and neuronal activity and behavior. Next, we describe mitochondrial transplantation's therapeutic potential in various CNS disorders. Finally, we discuss the basic and reverse-translation challenges of this approach that currently hinder the clinical use of mitochondrial transplantation.

Micromanipulation in Paramecium: From Non-Mendelian Inheritance to the Outlook for Versatile Micromachines

This review addresses nine areas of knowledge revealed by micromanipulations performed with Paramecium. Microinjection has shown that sexual maturation and senescence of Paramecium caudatum is a programmed process conducted by a specific gene and its product protein. In Paramecium tetraurelia, autogamy was revealed to depend on the number of DNA syntheses rather than the number of cell divisions in clonal aging. The cytoplasmic complementarity test established that microinjection of wild‐type cytoplasm can correct genetic defects of mutants. The concept of complementarity together with protein chemistry revealed compounds that control membrane excitability. In non‐Mendelian inheritance, noncoding small RNAs made from the parental micronucleus regulate the rearrangement of the progeny's macronuclear DNA. The macronucleus has the potential to be used as a factory for genetic engineering. The development and differentiation of progeny's nuclei in mating pairs are controlled by the parental macronucleus. The chemical reaction processes associated with exocytosis have been revealed by microinjection of various enzymes and antibodies. Using the fusion gene of histone H2B and yellow‐fluorescence protein, it was revealed that the fusion gene‐mRNA is transferred between cells during mating. Experiments with endosymbiotic bacteria and the host shed light on the conditions needed to establish sustainable symbiotic relationships.

Intracellular Delivery by Membrane Disruption: Mechanisms, Strategies, and Concepts

Intracellular delivery is a key step in biological research and has enabled decades of biomedical discoveries. It is also becoming increasingly important in industrial and medical applications ranging from biomanufacture to cell-based therapies. Here, we review techniques for membrane disruption-based intracellular delivery from 1911 until the present. These methods achieve rapid, direct, and universal delivery of almost any cargo molecule or material that can be dispersed in solution. We start by covering the motivations for intracellular delivery and the challenges associated with the different cargo types-small molecules, proteins/peptides, nucleic acids, synthetic nanomaterials, and large cargo. The review then presents a broad comparison of delivery strategies followed by an analysis of membrane disruption mechanisms and the biology of the cell response. We cover mechanical, electrical, thermal, optical, and chemical strategies of membrane disruption with a particular emphasis on their applications and challenges to implementation. Throughout, we highlight specific mechanisms of membrane disruption and suggest areas in need of further experimentation. We hope the concepts discussed in our review inspire scientists and engineers with further ideas to improve intracellular delivery.

Modifying the Mitochondrial Genome

Human mitochondria produce ATP and metabolites to support development and maintain cellular homeostasis. Mitochondria harbor multiple copies of a maternally inherited, non-nuclear genome (mtDNA) that encodes for 13 subunit proteins of the respiratory chain. Mutations in mtDNA occur mainly in the 24 non-coding genes, with specific mutations implicated in early death, neuromuscular and neurodegenerative diseases, cancer, and diabetes. A significant barrier to new insights in mitochondrial biology and clinical applications for mtDNA disorders is our general inability to manipulate the mtDNA sequence. Microinjection, cytoplasmic fusion, nucleic acid import strategies, targeted endonucleases, and newer approaches, which include the transfer of genomic DNA, somatic cell reprogramming, and a photothermal nanoblade, attempt to change the mtDNA sequence in target cells with varying efficiencies and limitations. Here, we discuss the current state of manipulating mammalian mtDNA and provide an outlook for mitochondrial reverse genetics, which could further enable mitochondrial research and therapies for mtDNA diseases.

Further characterization of the respiratory deficient dum-1 mutation of Chlamydomonas reinhardtii and its use as a recipient for mitochondrial transformation

The respiratory deficient dum-1 mutant of Chlamydomonas reinhardtii fails to grow in the dark because of a terminal 1.5 kb deletion in the linear 15.8 kb mitochondrial genome, which affects the apocytochrome b (CYB) gene. In contrast to the wild type where only mitochondrial genomes of monomer length are observed, the dum-1 genomes are present as a mixture of monomer and dimer length molecules. The mutant dimers appear to result from head-to-head fusions of two deleted molecules. Furthermore, mitochondrial genomes of dum-1 were also found to be unstable, with the extent of the deletion varying among single cell clones from the original mutant population. The dum-1 mutant also segregates, at a frequency of ca. 4% per generation, lethal minute colonies in which the original deletion now extends at least into the adjacent gene encoding subunit four of NAD dehydrogenase (ND4). We have used the dum-1 mutant as a recipient to demonstrate stable mitochondrial transformation in C. reinhardtii employing the biolistic method. After 4 to 8 weeks dark incubation, a total of 22 respiratory competent colonies were isolated from plates of dum-1 cells bombarded with C. reinhardtii mitochondrial DNA (frequency 7.3 x 10(-7)) and a single colony was isolated from plates bombarded with C. smithii mitochondrial DNA (frequency 0.8 x 10(-7)). No colonies were seen on control plates (frequency < 0.96 x 10(-9)). All transformants grew normally in the dark on acetate media; 22 transformants were homoplasmic for the wild-type mitochondrial genome typical of the C. reinhardtii donor. The single transformant obtained from the C. smithii donor had a recombinant mitochondrial genome containing the donor CYB gene and the diagnostic HpaI and XbaI restriction sites in the gene encoding subunit I of cytochrome oxidase (COI) from the C. reinhardtii recipient. The characteristic deletion fragments of the dum-1 recipient were not detected in any of the transformants.

A method for the amplification of Paramecium micronuclear DNA by polymerase chain reaction and its application to the central repeats of Paramecium primaurelia G surface antigen genes

This paper describes a method which allows the amplification of Paramecium micronuclear DNA. Amacronucleate cells are first obtained by an appropriate treatment with nocodazole, a microtubule depolymerizing agent which blocks the elongation of the macronucleus and the distribution of the micronuclei at cell division between the two daughter cells; then, DNA from such cells is amplified by the polymerase chain reaction technique. We have applied this method to the problem of the central repeats of the G surface antigen of P. primaurelia (strain 156). The central repeats consist of a 74 amino acid sequence repeated in tandem. The sequence identity of these repeats is also found in the nucleotide sequence even at silent codon positions, suggesting the existence of a mechanism of identity maintenance acting at the nucleotide level. Mechanisms based on RNA secondary structure which are frequently proposed as an explanation of this phenomenon are unlikely to be valid in this case. One can, therefore, imagine that these repeats might originate from one micronuclear sequence through duplicative processes which could occur during the formation of the macronucleus. We have used the described technique to amplify the micronuclear version of the central repeats and showed that it is identical to the macronuclear version, thus ruling out the above hypothesis. Therefore, intragenic recombination appears to be the most likely explanation of the sequence identity of these central repeats.

Stable and unstable transformation by microinjection of macronucleoplasm in Paramecium

Transformation by microinjection of macronucleoplasm in Paramecium caudatum was investigated. Macronucleoplasm with three genetic markers (behavior, trichocyst, and mating type) was injected into the macronucleus. To facilitate microinjection, in most cases, paramecia were immobilized in a gelatin (7.5%) solution. The injected cells began to express a dominant gene (cnrA+ or cnrB+) of the donor 9-24 hr after injection. Expression did not require cell division suggesting injected macronucleoplasm was capable of expressing a phenotype. The amount of injected macronucleoplasm appears to correlate with the frequency of successful expression but not to correlate with the time required for expression. After a number of fissions, the injected cells produced clones which had cells expressing the phenotype of the donor. This suggests that injected macronucleoplasm was replicated and expressed in the recipient cell lines. The transformed clones were classified into two groups. In one group, transformation was stable. All cell lines derived from the injected cells expressed a phenotype similar to the heterozygote of donor and recipient cells. In the other group, transformation was unstable. During the first five to seven fissions after injection, at each division, cells produced one daughter cell which later reverted to the recipient phenotype. After this unstable period, cells no longer produced the recipient phenotype but produced the donor phenotype exclusively. Donor and recipient phenotypes were, thus, segregated in different cell lines. Observation of genetic markers and analysis by computer simulation shed light on the mode of transmission of injected macronucleoplasm. In stable transformation, injected macronucleoplasm appears to be distributed equally to daughter cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Organelle transformation: shoot first, ask questions later

Transformation of mitochondria and chloroplasts is now possible by the application of microprojectile bombardment for the direct delivery of DNA to these organelles in living cells. Recent experiments have shown the feasibility of reverse genetic studies on mitochondrial and chloroplast genomes. Moreover, foreign or novel genes can now be stably introduced into mitochondria and chloroplasts, allowing the study of a much wider range of molecular genetic problems involving organelles than was previously possible.

Injection of mitochondria into human cells leads to a rapid replacement of the endogenous mitochondrial DNA

Isolated human mitochondria containing a mitochondrial DNA (mtDNA) coded chloramphenicol resistance marker were injected into cells from two different human sensitive cell lines, 143BTK- and HT1080-6TG, which had been partially depleted of their mtDNA by ethidium bromide treatment. On the basis of the available evidence concerning the tolerance of introduced volumes into mammalian cells, it is estimated that, on the average, less than one mitochondrion was introduced into each cell. Under selective conditions, the mitochondria became established in the recipient cells with a frequency greater than 2-3 x 10(-3). An analysis of multiple mtDNA and nuclear DNA polymorphisms revealed a rapid replacement of the resident mtDNA by the exogenous mtDNA. Six to ten weeks after microinjection, this replacement was complete in all but one of the HT1080-6TG transformants, and nearly complete in the majority of the 143BTK- transformants. The quantitative behavior of the mtDNA of the transformants at very early stages of selection strongly suggests that intracellular mtDNA selection played a crucial role in this replacement, with significant implications for mitochondrial genetics.

Transformation of Paramecium by microinjection of a cloned serotype gene

Paramecia of a given serotype express only one of several possible surface proteins called immobilization antigens (i-antigens). A 16-kilobase plasmid containing the gene for immobilization antigen A from Paramecium tetraurelia, stock 51, was injected into the macronucleus of deletion mutant d12, which lacks that gene. Approximately 40% of the injected cells acquired the ability to express serotype A at 34 degrees C. Expression appeared to be regulated normally. The transformed cells, like wild type, could be switched to serotype B by antiserum treatment and culture at 19 degrees C; on transfer to 34 degrees C, they switched back to serotype A expression. Many of the lines retained the ability to express serotype A until autogamy, when the old macronucleus is replaced by a new one derived from the micronucleus. DNA from transformants contained the injected plasmid sequences, which were replicated within the paramecia. No evidence for integration was obtained. The majority of replicated plasmid DNA comigrated with a linearized form of the input plasmid. Nonetheless, the pattern of restriction fragments generated by transformant DNA and that generated by input plasmid DNA are identical and consistent with a circular rather than a linear map. These conflicting observations can be reconciled by assuming that a mixture of different linear fragments is present in the transformants, each derived from the circular plasmid by breakage at a different point. Copy-number determinations suggest the presence of 45,000-135,000 copies of the injected plasmid per transformed cell. These results suggest that the injected DNA contains information sufficient for both controlled expression and autonomous replication in Paramecium.

A mutation affecting basal body duplication and cell shape in Paramecium

The thermosensitive mutant sm19 of Paramecium tetraurelia undergoes a progressive reduction in cell length and basal body number over successive divisions at the nonpermissive temperature of 35 degrees C. In spite of these defects, sm19 cells retain the same generation time as wild-type cells at 35 degrees C. Cytological observations at both electron and light microscopy levels reveal no other perturbation than the rarefaction of basal bodies and the rare (3%) absence of one or two microtubules in basal bodies or ciliary axonemes. The temperature-sensitive period, during the last 30 min of the cell cycle, corresponds to the phase of basal body duplication. Upon transfer back to the permissive temperature, all basal bodies are normally duplicated. The mutational defect is transiently restored by microinjection of wild-type cytoplasm or of a soluble proteic fraction from wild-type cell homogenates. Altogether, the cytological and physiological data support the conclusion that the sm19+ gene codes for a diffusible product required for the initiation of basal body duplication and would thus be the first identified gene involved in this process. Our data also indicate that in Paramecium basal body number is not coupled with control of the cell cycle, but helps determine the shape of the cell via the organization of the cytoskeleton.

Clonal aging in Paramecium tetraurelia. II. Evidence of functional changes in the macronucleus with age

The contribution of the macronucleus of Paramecium tetraurelia to the long term proliferation potential of a cell line was tested using a nuclear transplantation protocol. Macronuclei from young or old wild-type cells were injected into genetically marked host cells of a standard clonal age. The subsequent proliferation to clonal death of successfully and stably transformed hybrids was compared to the proliferation of injected but untransformed lines (injection controls). Young macronuclear donor material significantly prolonged the proliferation of the hybrid cell lines over that of the injection controls, but old donor material caused only a slight increase in post-injection proliferation of the hybrids. Total cell proliferation was also considered. Comparison of the total life spans of injected, non-transformed lines with uninjected host controls demonstrates that the injection itself has no significant effect upon proliferation potential. The mean life spans of uninjected donor controls and the mean total life spans of the transplanted macronuclear material (donor age at injection plus subsequent hybrid proliferation) are similar, regardless of the age of the donor at the time of transplantation. These results suggest that there is an age-related decrease in the ability of a macronucleus to support subsequent cell growth and division. The results also show that the proliferation potential of the donor macronucleus does not appear to be changed to any great degree by transplantation into a host cell of different clonal age. The macronucleus thus "remembers its age" after transplantation. Coupled with an absence of any detectable cytoplasmic effects upon aging during vegetative growth, these results argue in favor of a macronuclear determination of the proliferation potential of a cell line. The identification of a macronuclear basis for clonal aging in P. tetraurelia should permit a better directed approach for further research in this area.

Is the initiation of macronuclear DNA synthesis in Euplotes dependent on micronuclear functions?

To determine whether the micronucleus makes essential contributions during asexual reproduction, observations were made on cells of Euplotes octocarinatus from which the micronucleus had been removed with a micropipette. Most cells underwent one postenucleation division, then became arrested in macronuclear G1, slowed down in food uptake, developed macronuclear deformations, and finally died. Such cells could be rescued if a micronucleus was reimplanted before macronuclear deformations had developed. When provided with a new micronucleus, cells initiated macronuclear DNA synthesis about 12-16 h later. The data suggest that the micronucleus is involved in the control of the cell's transition from macronuclear G1 to S, and a model is proposed which postulates that in Euplotes macronuclear DNA synthesis is initiated when a micronucleus-encoded "initiator protein" has accumulated to a critical amount.

Trichocyst phenotype transformation induced by macronuclear transplantation in Paramecium tetraurelia

A portion of the macronucleus of wild-type cells of Paramecium tetraurelia was removed and was injected into cells homozygous for the ftA mutation. The ftA mutants make defective trichocysts and are unable to perform normal trichocyst exocytosis. After injection, approx. 30% of the surviving cells show a phenotype shift from mutant to wild-type. This shift is stable during subsequent vegetative growth until clonal death. If, however, the hybrid cell lines are brought to autogamy (which discards the existing macronucleus and forms a new one from sexual products derived from a micronucleus), then the lines revert to the ftA phenotype. Since micronuclei were not transplanted, the phenotypic reversion after autogamy is to be expected, and demonstrates that the transformation affects the macronucleus only. A second series of injections involved transfer of a portion of the macronucleus from cells homozygous for the trichocyst ptA mutation into ftA host cells. These two mutations are genetically complementary, so the injection should be genetically equivalent to forming a double heterozygote. Approx. 20% of the injection survivors shift to wild-type. This shift is also vegetatively stable unless autogamy occurs; after autogamy, reversion to the ftA phenotype is seen. These results show that a portion of a macronucleus can be successfully transplanted from one cell to another and that, in the host cytoplasmic environment, normal gene expression and replication of a transplanted macronucleus does occur. The technique of macronuclear transplantation is significant to studies of the macronuclear contribution to clonal aging, and to studies on genetic control over trichocyst development.

Clonal aging in Paramecium tetraurelia. Absence of evidence for a cytoplasmic factor

Cells of Paramecium tetraurelia show clonal aging with characteristics comparable to the aging seen in tissue culture cell lines. An investigation is underway to determine the relative contributions, if any, of the cytoplasm and the macronucleus to the onset of senescence. Using a microinjection protocol, the importance of the cytoplasm to aging was tested. Cytoplasm was transferred from young cells into old cells to see if the mean age of death of the injected cell lines could be increased, compared with uninjected controls and sham injected controls. Cytoplasm from old cells was transferred into young cells to see if the mean age of death of the injected cell lines could be decreased, compared with sham injected and uninjected controls. In neither case was there any statistically significant change in mean ages of death. Furthermore, no changes can be demonstrated even with a protocol which transplanted 3 times the normal cytoplasmic volume. Thus, a cytoplasmic effect upon vegetative aging in P. tetraurelia cannot be demonstrated. Tests of a macronuclear influence are now underway.

Resistance of germinal nucleus to aging in Paramecium: evidence obtained by micronuclear transplantation

A diversity of time when increase in mortality after conjugation occurs during the lifespan was found in subclones of three stocks of Paramecium caudatum. A possible micronuclear contribution to the increase in sterility has been investigated by micronuclear transplantation. We found two classes of micronuclei in aged clones: those that can function normally if the cytoplasmic environment is young, and those that cannot, even in a young cytoplasmic environment. The results indicate that in the former, the age-dependent increase in sterility is due to a deleterious macronucleus and/or cytoplasm, and in the latter it is due to micronuclear damage. The micronuclear damage in aged clones is probably induced by a deleterious cytoplasmic environment because aged clones with transplanted young micronuclei showed an abrupt decrease in progeny survival between 14 and 42 cell divisions after transplantation. Overall, the micronucleus seems not to be a source of age-related damage but rather is subjected to damage from macronuclear and/or cytoplasmic sources.

Synchronous exocytosis in Paramecium cells. I. A novel approach

From a total number of approximately 1100-1300 secretory organelles ("trichocysts") in a Paramecium tetraurelia cell, approximately 90% are docked to the cell membrane. Approximately 90% of this subpopulation can be discharged from the cells within seconds, when exposed to the novel trigger agent aminoethyldextran (AED) at a concentration of 10(-6) M. No deleterious side effects were recognized with this trigger agent even over long time periods. By application of AED close to cells with the use of a micropipette we found that triggering of trichocyst release by AED involves a local, non-propagated effect and that all regions of the cell body are equally reactive. It requires exogenous Ca2+. It is independent of ciliary Ca2+ channels, since deciliated cells or ciliary mutations with "Ca2+-tight" cilia respond to AED with normal exocytosis performance. The massive and rapid occurrence of trichocyst release in response to AED allowed for a freeze-fracture analysis of intramembraneous changes (see Olbricht et al., Exp cell res 151 (1984) 14 [23]) which also shows the involvement of exocytosis) as well as for a long-term study of the re-attachment of trichocysts (see Haacke & Plattner, Exp cell res 151 (1984) 21 [10]) under synchronous conditions.

Microsurgical analysis of the clonal age and the cell-cycle stage required for the onset of autogamy in Paramecium tetraurelia

When autogamy was induced in competent cells of Paramecium tetraurelia by depriving them of food, the onset of autogamy was preceded by a critical fission which occurred in the starvation medium. When the cells were fed again immediately after the fission, they did not undergo autogamy. However, they did undergo autogamy when they were fed later than 1 hr after the critical fission. The irreversible differentiation for autogamy seems to be at about 1 hr after the critical fission. This procedure thus provides the opportunity to induce autogamy synchronously. The result of macronuclear transplantation demonstrated that autogamy was under the control of macronucleus. Moreover, the clonal age required for autogamy was found to be shortened by repetitive elimination of a part of the macronucleus. The result can be explained by the hypothesis that clonal age is measured in rounds of chromosome replication or DNA synthesis rather than cell divisions.

Induction of autogamy by transfer of macronuclear karyoplasm in Paramecium tetraurelia

Macronuclear karyoplasm was transplanted from pre-autogamous donor cells (clonal age, 22 fissions) into the macronucleus of young recipient cells (2 fissions after autogamy occurred) by means of microinjection. A reciprocal experiment was carried out by injecting karyoplasm from young clonal age donors into pre-autogamous recipients. In the case of karyoplasm transfer from pre-autogamous donors to young recipients, autogamy occurred early in 67% of injected cells, whereas reciprocal injections had no influence on the onset of autogamy, and all of the injected cells underwent autogamy. Such results indicate a distinct role of pre-autogamous cells of macronucleus in the induction of autogamy.

Microinjection of cytoplasm as a test of complementation in Paramecium

Mutants in Paramecium tetraurelia, unable to generate action potentials, have been isolated as cells which show no backward swimming in response to ionic stimulation. These "pawn" mutants belong to at least three complementation groups designated pwA, pwB, and pwC. We have found that microinjection of cytoplasm from a wild-type donor into a pawn recipient of any of the three complementation groups restores the ability of the pawn to generate action potentials and hence swim backward. In addition, the cytoplasm from a pawn cannot restore a recipient of the same complementation group, but that from a pawn of a different group can. Electrophysiological analysis had demonstrated that the restoration of backward swimming is not due to a simple addition of ions but represents a profound change in the excitable membrane of the recipient pawn cells. Using known pawn mutants and those which had previously been unclassified, we have been able to establish a perfect concordance of genetic complementation and complementation by cytoplasmic transfer through microinjection. This method has been used to classify pawn mutants that are sterile or hard-to-mate and to examine the ability of cytoplasms from different species of ciliated protozoa to restore the ability to swim backward in the pawn mutants of P. tetraurelia. A cell homogenate has also been fractionated by centrifugation to further purify the active components. These results demonstrate that transfer of cytoplasm between cells by microinjection can be a valid and systematic method to classify mutants. This test is simpler to perform than the genetic complementation test and can be used under favorable conditions in mutants that are sterile and in cells of different species.

Control of exocytotic processes: cytological and physiological studies of trichocyst mutants in Paramecium tetraurelia

The trichocysts of Paramecium tetraurelia constitute a favorable system for studying secretory process because of the numerous available mutations that block, at various stages, the development of these secretory vesicles, their migration towards and interaction with the cell surface, and their exocytosis. Previous studies of several mutants provided information (a) on the assembly and function of the intramembranous particles arrays in the plasma membrane at trichocyst attachment sites, (b) on the autonomous motility of trichocysts, required for attachment to the cortex, and (c) on a diffusible cytoplasmic factor whose interaction with both trichocyst and plasma membrane is required for exocytosis to take place. We describe here the properties of four more mutants deficient in exocytosis ability, nd6, nd7, tam38, and tam6, which were analyzed by freeze-fracture, microinjection of trichocysts, and assay for repair of the mutational defect through cell-cell interaction during conjugation with wild-type cells. As well as providing confirmation of previous conclusions, our observations show that the mutations nd6 and tam6 (which display striking abnormalities in their plasma membrane particle arrays and are reparable through cell-cell contact but not by microinjection of cytoplasm) affect two distinct properties of the plasma membrane, whereas the other two mutations affect different properties of the trichocysts. Altogether, the mutants so far analyzed now provide a rather comprehensive view of the steps and functions involved in secretory processes in Paramecium and demonstrate that two steps of these processes, trichocyst attachment to the plasma membrane and exocytosis, depend upon specific properties of both the secretory vesicle and the plasma membrane.

Genetic interactions in the control of mitochondrial function in Paramecium. II. Interactions between nuclear and mitochondrial genomes

In an attempt to understand the genetic interactions between nuclear and mitochondrial genomes leading to mitochondrial biogenesis, different combinations of known nuclear and mitochondrial mutations have been constructed by microinjection. Eleven different tetrazolium resistant mutant strains, many clearly affecting mitochondrial function, were injected with mitochondria from four different erythromycin resistant mitochondrial mutants. Cases were found in which mutant mitochondria were unable to replicate in tetrazolium resistant mutants. The successful mitochondrial transfers were characterized for growth rate, temperature and cold sensitivity. Several selected combinations were characterised also for cytochrome spectra and cyanide resistance. Many different phenotypes were produced by the interaction of the different nuclear and mitochondrial mutations. These ranged from a positive interaction in which mutant mitochondria were selected by a nuclear mutant in preference to wild-type, through apparent absence of interaction, to negative interaction in which the mitochondrial-nuclear combination was temperature sensitive even though both 'parents' were thermoresistant. The possible molecular basis of these interactions is discussed.

Control of membrane fusion in exocytosis. Physiological studies on a Paramecium mutant blocked in the final step of the trichocyst extrusion process

Previous studies on exocytosis in Paramecium using mutants affecting trichocyst extrusion permitted us to analyze the assembly and function of three intramembrane particle arrays ("ring" and "rosette" in the plasma membrane, "annulus" in the trichocyst membrane) involved in the interaction between these two membranes. Using a conditional mutation, nd9, which blocks rosette assembly and prevents exocytosis at the nonpermissive temperature, we have analyzed the effect of temperature on the secretory capacity of nd9 cells. By combining several techniques (physiological studies, microinjections, inhibition of fatty acid synthesis, and freeze-fracture analysis) we demonstrate (a) that the product of the mutated allele nd9 is not thermolabile but that its activity is dependent upon temperature-induced changes in the membrane lipid composition and (b) that the product of the nd9 locus is a diffusible cytoplasmic component whose interaction with both plasma membrane and trichocyst membrane is required for rosette assembly and exocytosis. The data provide physiological evidence for the existence of a molecular complex(es) linking the two membranes and involved in the control of membrane fusion; we discuss the possible nature and function of these links.

Characterization of mitochondrial and cytoplasmic ribosomes from Paramecium aurelia

The ribosomes extracted from the mitochondria of the ciliate, Paramecium aurelia, have been shown to sediment at 80S in sucrose gradients. The cytoplasmic ribosomes also sediment at 80S but can be distinguished from their mitochondrial counterparts by a number of criteria. Lowering of the Mg++ concentration, addition of EDTA, or high KCl concentrations results in the dissociation of the cytoplasmic ribosomes into 60S and 40S subunits, whereas the mitochondrial ribosomes dissociate into a single sedimentation class at 55S. Furthermore, the relative sensitivity of the two types of ribosome to dissociating conditions can be distinguished. Electron microscopy of negatively stained 80S particles from both sources has also shown that the two types can be differentiated. The cytoplasmic particles show dimensions of 270 X 220 A whereas the mitochondrial particles are larger (330 X 240 A). In addition, there are several distinctive morphological features. The incorporation of [14C]leucine into nascent polypeptides associated with both mitochondrial and cytoplasmic ribosomes has been shown: the incorporation into cytoplasmic 80S particles is resistant to erythromycin and chloramphenicol but sensitive to cycloheximide, whereas incorporation into the mitochondrial particles is sensitive to erythromycin and chloramphenicol but resistant to cycloheximide.

The Leeuwenhoek lecture, 1976: protozoa and genetics

This paper is a discussion of the value of protozoa as experimental organisms for the study of certain genetic problems. A number of examples of ‘cytoplasmic heredity’ are considered, some being based on DNA-containing particles, and others lacking such a material basis. Examples of the first type are the endosymbionts, such as kappa, and mitochondria; an example of the second type is the system of antigenic variation inParamecium. Brief mention is made of some studies on nucleo-cytoplasmic interactions inAmoeba, of the kinetoplast inTrypanosoma, and of some studies on the genetics of malaria parasites (Plasmodium bergheiand related species). As a final example of the value of protozoa in experimental research, reference is made to some behavioural mutants ofParameciumand the bearing of this work on some neurophysiological problems is indicated.

Interspecies transfer of mitochondria in Paramecium aurelia

Erythromycin-resistant mitochondria from species 1, 5 and 7 of P. aurelia were injected into erythromycin-sensitive paramecia of each of the same three species. Mitochondria from species 1 and 5 were successfully transferred to all three species, but species 7 mitochondria failed to develop in species 1 and 5. Minor differences were indicated in the frequency of successful transfers of species 1 mitochondria into species 1 and 5 cells. From studies on the transferability of mitochondria from "hybrid" cells, containing mitochondria from one species and nuclei from another, it was concluded that mitochondrial compatibility was mainly under control of the nuclear genome, with a possible minor control also by the mitochondrial genome.

Control factor of nuclear cycles in cilate conjugation: cell-to-cell transfer in multicellular complexes

Multicellular complexes of Blepharisma intermedium are regularly produced by treating doublet cells with the gamone of complementary mating type. Cells remain united without undergoing nuclear cycles of conjugation. However, if a cell of complementary mating type unites, nuclear cycles begin at the site of this union and propagate all through the multicellular complex.