Nuclear Lethal Effect and Nucleocytoplasmic Incompatibility Induced by Endosymbionts in Amoeba proteus1

ABSTRACT. The role of bacterial endosymbionts in the acquisition of new phenotypic characters was studied by transplanting nuclei from an uninfected strain of Amoeba proteus into the enucleated cytoplasm of a symbiont-carrying strain. After 1–10 cell cycles, the nuclei were tested for two characters: compatibility with uninfected and infected cytoplasm, and their lethal effect against amoebae of the uninfected parent strain. A significant number of transplanted nuclei displayed both of the new phenotypic traits after a few divisions in the infected cytoplasm. Thus the influence of these endosymbionts on the nucleus of A. proteus was virtually instantaneous.     

Effect of diazotrophic bacterium inoculation and organic fertilization on yield of Champaka pineapple intercropped with irrigated sapota

The purpose of this study was to evaluate the response of the ‘Champaka’ pineapple to inoculation with the diazotrophic bacterium Asaia bogorensis (strain 219) when grown with organic fertilizer in an irrigated sapota orchard. Plantlets were transplanted to tubes containing a mixture of worm compost and vermiculite and inoculated with 10⁸ bacterial cells. After five and a half months of acclimatization the plantlets were transplanted in furrows in the sapota orchard. Fertilizer was placed at the bottom of the furrows and covered with three doses (2.5; 5.0 and 7.5 L linear m^?1 row) of three organic composts. The successful association of the plantlets with the diazotrophic bacterium was confirmed by most probable number analysis before transferring to the field. Plants inoculated with strain AB219 showed the greatest initial leaf growth and produced the heaviest fruits compared to uninoculated plants. Plant growth and fruit yield increased with increasing compost dosages. The results suggested that ‘Champaka’ pineapple benefited from the association of A. bogorensis (strain 219) when grown under irrigation and with organic fertilizer.     

Positional control of the fates of nuclei produced after meiosis in Paramecium caudatum: Analysis by nuclear transplantation

The survival or degeneration of nuclei produced by meiosis in Paramecium caudatum depends on their position in the cytoplasm. The surviving nucleus always lies in the special region of the cytoplasm called the paroral region, which is the region around the cytostome. The remaining three degenerate outside the region. The mechanism controlling the survival or degeneration of meiotic nuclei was analyzed microsurgically. When the nucleus in the early conjugating cells (stage II) was transplanted into the cell at the stage when three meiotic nuclei were degenerating, it did not degenerate, but divided. When one of the meiotic nuclei which was outside the paroral region and destined to degenerate was transplanted into the cell in the meiotic prophase (stage IV), it did not survive but degenerated. When the surviving nucleus in the paroral region was removed microsurgically, one of the three meiotic nuclei lying outside the paroral region and destined to degenerate moved into the paroral region and survived. These results suggest that the nuclei after meiosis are destined to degenerate but can be rescued from degeneration by the special environment of the paroral region.     

Transfer of Isolated Nuclei into Protoplasts of Trichoderma harzianum

Protoplasts released from young hyphae of Trichoderma harzianum contained 0 to 10 nuclei per protoplast, and most (about 80%) contained from 4 to 6 nuclei. Most protoplasts were larger than 3 μm in diameter. Nuclei were isolated from protoplasts of an auxotrophic mutant of T. harzianum and transferred into protoplasts obtained from another auxotroph of the same strain. This intrastrain nuclear transfer gave rise to numerous progeny which were stable, prototrophic, and heterokaryotic. Interstrain transfers in which nuclei from a wild-type prototroph of one strain were transferred into protoplasts from a lysine-deficient auxotroph of a second strain were also done. Heterokaryotic progeny were recovered from these interstrain transfers when the regenerating protoplasts were provided with a low concentration of lysine 48 h after the initial plating. Heterokaryotic progeny contained 11 to 17% of donor-type nuclei. Progeny homokaryotic for donor-type nuclei were obtained as single-spore isolates. These homokaryotic isolates expressed the isozyme pattern and colony morphology phenotype of the nuclear donor. When regenerating protoplasts were provided with lysine 10 days after the initial plating, only a single progeny was obtained. However, single-spore subprogeny of this nuclear transfer were prototrophic and exhibited a wide range of unstable morphological phenotypes.     

Development, distribution, and characteristics of intrinsic, nonbacterial ice nuclei in prunus wood

Ice nuclei active at approximately −2°C and intrinsic to woody tissues of Prunus spp. were shown to have properties distinct from bacterial ice nuclei. Soaking 5-centimeter peach stem sections in water for 4 hours lowered the mean ice nucleation temperature to below −4°C, nearly 2°C lower than stems inoculated with ice nucleation-active Pseudomonas syringae strain B301D. Ice nucleation activity in peach was fully restored by air-drying woody stem sections for a few hours. The ice nuclei in woody tissue were inactivated between 40 and 50°C, but unaffected by treatment with bacterial ice nucleation inhibitors (i.e. NaOCl, tartaric acid, Triton XQS-20), sulfhydryl reagents (i.e. p-hydroxymercuribenzoate and iodine) and Pronase. Ice nuclei could not be dislodged from stems by sonication and were shown to be equally distributed in peach bud and internodal stem tissue on a per unit mass basis; outer and inner stem tissues were also indistinguishable in ice nucleation activity. Development of ice nuclei in immature peach and sweet cherry stems did not occur until midsummer and their formation was essentially complete by late August. Once formed the ice nuclei intrinsic to woody stems were stable and unaffected by seasonal changes in growth. The apparent physiological function of the ice nuclei is discussed in relation to supercooling and mechanisms of cold hardiness in Prunus spp.     

Ice Nucleation Activity in Fusarium acuminatum and Fusarium avenaceum

Twenty fungal genera, including 14 Fusarium species, were examined for ice nucleation activity at −5.0°C, and this activity was found only in Fusarium acuminatum and Fusarium avenaceum. This characteristic is unique to these two species. Ice nucleation activity of F. avenaceum was compared with ice nucleation activity of a Pseudomonas sp. strain. Cumulative nucleus spectra are similar for both microorganisms, while the maximum temperatures of ice nucleation were −2.5°C for F. avenaceum and −1.0°C for the bacteria. Ice nucleation activity of F. avenaceum was stable at pH levels from 1 to 13 and tolerated temperature treatments up to 60°C, suggesting that these ice nuclei are more similar to lichen ice nuclei than to bacterial ones. Ice nuclei of F. avenaceum, unlike bacterial ice nuclei, pass through a 0.22-μm-pore-size filter. Fusarial nuclei share some characteristics with the so-called leaf-derived nuclei with which they might be identified: they are cell free and stable up to 60°C, and they are found in the same kinds of environment. Highly stable ice nuclei produced by fast-growing microorganisms have potential applications in biotechnology. This is the first report of ice nucleation activity in free-living fungi.     

THE CYTONUCLEOPROTEINS OF AMEBAE : II. Some Aspects of Cytonucleoprotein Behavior and Synthesis

Radioactivity, apparently in cytonucleoproteins, from an amino acid-labeled nucleus implanted into a non-radioactive cell appeared in the host nucleus within 10 minutes, and the typical equilibrium ratio 70:30 donor nucleus radioactivity:host nucleus radioactivity was reached in 4 to 5 hours at 25°C. If such binucleates grew and divided, no localization of radioactivity was observable in cells fixed during mitosis, but the protein label remained concentrated in the daughter interphase nuclei for at least 4 generations. Continued migration of cytonucleoproteins was observed if these daughter nuclei were transplanted to other unlabeled cells. The Q₁₀ (19° to 29°C) of the migration rate of radioactive cytonucleoproteins was ca. 1.3, suggesting that passage through the cytoplasm occurred by diffusion. Both non-migratory nuclear proteins and cytonucleoproteins appear to be synthesized in the cytoplasm.     

Nuclear buoyant density determination and the purification and characterization of wild-type neurospora nuclei using percoll density gradients

A procedure has been developed using Percoll density gradients for the isolation and purification of nuclei from germinated conidia of wild-type Neurospora crassa St. Lawrence strain 74A. Crude nuclei were purified isopycnically in gradients of Percoll, which is silica coated with polyvinylpyrrolidone. A DNA:RNA:protein ratio of 1:3.5:6.5 was found in purified nuclei. Cytoplasmic contamination was found to be negligible in the nuclear preparations, as determined by electron microscopy and by following a radioactively-labeled ribosome tag during the isolation procedure. A small amount of endogenous ribonuclease activity was detected in the crude nuclear preparations, but not in suspensions of nuclei purified in the Percoll gradients. Ribosomal RNA was extracted from the nuclei in good yields, and electrophoretic analysis indicated the presence of precursor rRNA molecules, as well as the mature 17S and 25S rRNA species. Using the Percoll gradient system, the buoyant density of purified Neurospora nuclei was determined to be 1.08 grams per milliliter based on refractive index measurements.     

The fate of cryptophyte cell organelles in the ciliate Mesodinium cf. rubrum subjected to starvation

Mesodinium rubrum Lohmann is a mixotrophic ciliate and one of the best studied species exhibiting acquired phototrophy. To investigate the fate of cryptophyte organelles in the ciliate subjected to starvation, we conducted ultrastructural studies of a Korean strain of M. cf. rubrum during a 10 week starvation experiments. Ingested cells of the cryptophyte Teleaulax amphioxeia were first enveloped by ciliate membrane, and then prey organelles, including ejectisomes, flagella, basal bodies and flagellar roots, were digested. Over time, prey nuclei protruded into the cytoplasm of the ciliate, their size and volume increased, and their number decreased, suggesting that the cryptophyte nuclei likely fused with each other in the ciliate cytoplasm. At 4 weeks of starvation, M. cf. rubrum cells without cryptophyte nuclei started to appear. At 10 weeks of starvation, only two M. cf. rubrum cells still possessing a cryptophyte nucleus had relatively intact chloroplast-mitochondria complexes (CMCs), while M. cf. rubrum cells without cryptophyte nuclei had a few damaged CMCs. This is the first ultrastructural study demonstrating that cryptophyte nuclei undergo a dramatic change inside M. cf. rubrum in terms of size, shape, and number following their acquisition.     

Analysis of localization of cell-cycle regulators in Neurospora crassa

Most fungi are multinucleated organisms. In some fungi, they have asynchronous nuclei in the same cytoplasm. We analyzed a cell-cycle regulation mechanism using a model fungus Neurospora crassa, which can make heterokaryon cells. G1/S cyclin CLN-1 and cyclin-dependent kinase CDC-2 were tagged with different fluorescence in different strains and expressed. By forming a heterokaryon strain of these, two different fluorescence-tagged proteins were expressed in the same cytoplasm. CDC-2 was localized in all nuclei, whereas CLN-1 was not detected in most of the nuclei and was dispersed in the cytoplasm with small granular clusters. This indicates that in multinucleated fungi, cell-cycle regulators, similar to other proteins, are shared around the nuclei regardless of different cell-cycle stages. Moreover, each nucleus can select and use a special cell-cycle regulator only when it is necessary. Fungal nuclei may have a novel pickup mechanism of necessary proteins from their cytoplasm at the point of use.     

The effects of inbreeding and low temperature on the pattern of chromosome synapsis in the ovarian nurse cell nuclei of Drosophila melanogaster strains

The effects of inbreeding and low temperature on the pattern of homologous chromosome synapsis in ovarian nurse cell nuclei of Drosophila melanogaster strains were studied. Exposure to decreased temperature (16°C) caused a noticeable increase in the rate of asynapses of homologous chromosomes, whereas this effect was insignificant for F₃₀ inbreeding generation. Long-term inbreeding has a substantial effect on the relative positions of chromosomes in the nurse cell nuclei. This is visually evident only in the interstrain hybrids between highly inbred strains LA (F₉₂₈) and HA (F₉₂₈) or between either strain and laboratory strain Canton S or the flies from the natural population, where abnormalities in homologous chromosome synapsis are observed in virtually all nuclei.     

Cytological observations on the interaction between two inversions responsible for position-effect variegation in Drosophila melanogaster

The strain of Drosophila melanogaster In (1)m ^k ; In (2LR) Rev ^B shows more miniature variegation than the strain In(1)m ^K and less Revolute variegation than the strain In(2LR)Rev ^B . Observations on heterochromatisation in the larval salivary gland chromosomes of the three strains revealed that the m ^k chromosome is heterochromatised in a higher proportion of nuclei and the Rev ^B chromosome is heterochromatised in a lower proportion of nuclei in the double-inversion strain than in the corresponding single-inversion strain. Single-and double-inversion strains did not however differ in the mean number of bands heterochromatised per affected chromosome. The difference between incidence and extent of heterochromatisation was further exposed by comparisons between and within strains: the incidence of heterochromatisation in different chromosome regions within a nucleus was positively correlated, but a significant positive correlation was found in only one of the eight possible comparisons between extents of heterochromatisation in different chromosome regions in a given nucleus, two of the comparisons showing significantly negative correlations. The results in general are compatible with the view that the initiation and progression of heterochromatisation are distinct phenomena, under separate control.     

Transplantation of insect giant chromosome nuclei into amphibian oocytes

Polytene salivary gland nuclei of Chironomus pallidivittatus were transplanted into oocytes of Xenopus laevis which were then cultured in vitro for 18 h. The giant chromosomes and nucleoli as well as the entire nuclei enlarged considerably in volume during this time. The polyteny and specific chromomere pattern of the chromosomes were maintained, and the puffing of the salivary gland-specific Balbiani rings was not noticeably changed. — Polytene nuclei from differentiated insect cells transplanted into Xenopus oocytes thus appear suited for exposing giant chromosomes in vivo to purified factors such as regulatory molecules. This paper is dedicated to Professor Wolfgang Beermann on the occasion of his 60th birthday     

Cytoplasmic Bulk Flow Propels Nuclei in Mature Hyphae of Neurospora crassa

We used confocal microscopy to evaluate nuclear dynamics in mature, growing hyphae of Neurospora crassa whose nuclei expressed histone H1-tagged green fluorescent protein (GFP). In addition to the H1-GFP wild-type (WT) strain, we examined nuclear displacement (passive transport) in four mutants deficient in microtubule-related motor proteins (ro-1, ro-3, kin-1, and a ro-1 kin-1 double mutant). We also treated the WT strain with benomyl and cytochalasin A to disrupt microtubules and actin microfilaments, respectively. We found that the degree of nuclear displacement in the subapical regions of all strains correlated with hyphal elongation rate. The WT strain and that the ro-1 kin-1 double mutant showed the highest correlation between nuclear movement and hyphal elongation. Although most nuclei seemed to move forward passively, presumably carried by the cytoplasmic bulk flow, a small proportion of the movement detected was either retrograde or accelerated anterograde. The absence of a specific microtubule motor in the mutants ro-1, ro-3, or kin-1 did not prevent the anterograde and retrograde migration of nuclei; however, in the ro-1 kin-1 double mutant retrograde migration was absent. In the WT strain, almost all nuclei were elongated, whereas in all other strains a majority of nuclei were nearly spherical. With only one exception, a sizable exclusion zone was maintained between the apex and the leading nucleus. The ro-1 mutant showed the largest nucleus exclusion zone; only the treatment with cytochalasin A abolished the exclusion zone. In conclusion, the movement and distribution of nuclei in mature hyphae appear to be determined by a combination of forces, with cytoplasmic bulk flow being a major determinant. Motor proteins probably play an active role in powering the retrograde or accelerated anterograde migrations of nuclei and may also contribute to passive anterograde displacement by binding nuclei to microtubules.Organelle movement and positioning are important aspects of cell growth and differentiation (19, 20, 27, 35). Movement and positioning of nuclei are especially important because of their implications in mitotic divisions during hyphal growth and asexual sporulation (conidiation), as well as fertilization events leading to meiosis and ascospore formation during sexual development (1, 3, 33). In yeast, nuclei move comparatively short distances (20, 32), whereas in filamentous fungi nuclei are typically transported over long distances within hyphae (1, 34, 35).Movement of nuclei in fungal cells may be either an active or a passive process. Early studies of filamentous fungi showed nuclei uniformly distributed along the entire hypha; they appeared to move with the growing hyphal apex, keeping a more or less constant distance from the cell tip. Such evidence pointed to passive displacement of nuclei by cytoplasmic bulk flow (10-12, 24), a role confirmed in our recent study on the dynamics of the microtubular cytoskeleton (28) and supported by studies with injected lipid droplets (17). Upon the discovery of motor proteins and their role in nuclear migration and positioning in filamentous fungi, attention was primarily focused on the participation of motors in nuclear events, including the movement of nuclei during hyphal extension (15, 25, 26, 29, 37), while the role of cytoplasmic bulk flow was largely discounted or disregarded.Whereas much effort has been directed toward the characterization of the components involved in motor-driven nuclear transport, the relative importance of passive nuclear propulsion has remained an open question. For the purpose of distinguishing clearly between active migration and passive displacement, we will consider “migration” to mean an active, motor-dependent process, while “displacement” will refer to passive transport of nuclei within the hypha. “Movement” refers either to active or passive transport of nuclei through hyphae. Here, we used strains of Neurospora crassa whose nuclei were tagged with green fluorescent protein (GFP) to examine the dynamics and distribution of nuclei in growing hyphae. In addition to evaluating nuclear movement in a wild-type (WT) strain, we examined the dynamics of nuclear movement in mutants defective in microtubule-related motor proteins: a ro-1 mutant for its deficiency in the heavy chain of dynein, a ro-3 mutant deficient in the dynactin p150^glued subunit, a kin-1 mutant deficient in conventional kinesin, and a ro-1 kin-1 a dynein-kinesin double mutant. We also tested the effect of drugs that inhibit specifically microtubules and actin microfilaments. Our study demonstrates that passive displacement plays a major role in nuclear dynamics in growing hyphae of N. crassa.     

Protoplast fusion between Aspergillus oryzae and Aspergillus niger in relation to their multinuclear nature

Protoplasts of cycloheximide-resistant strains from Aspergillus oryzae IFO 5239 were fused with those of kabicidin-resistant strains from Aspergillus niger IFO 4407. By nuclear staining in conidia, it appeared that all of the fusant conidia had two kinds of nuclei. Small nuclei seemed to be derived from A. oryzae and large nuclei seemed to be derived from A. niger. However, three types of antibiotic resistance were shown among the conidia of fusants. Almost all were kabicidin resistant. Conidia of fusants were multinuclear and had various DNA contents and various sizes. By the comparison with the growth rates of parental strains, the growth rates of A. niger were superior to those of A. oryzae. The inclination in the distribution of antibiotic resistance of fusant conidia seemed to owe more to the differences of growth rates between parental strains than the influence of the multinucleate nature of a parental strain.     

Competitiveness of endophytic Phialocephala fortinii s.l. – Acephala applanata strains in Norway spruce roots

Dark septate endophytes of the Phialocephala fortinii s.l. – Acephala applanata species complex (PAC) are presumed to be the most abundant root colonizing endophytes of conifers across the Northern hemisphere. To test the competitiveness of different PAC strains, PAC-free Picea abies saplings were inoculated with five different PAC strains by planting them in pre-colonized substrates. Saplings were left to grow for six weeks and then transplanted crosswise into a substrate colonized by one of the other four strains for a further two weeks. PAC were isolated and genotyped using microsatellite markers. The power of colonization, i.e. the ability of colonizing roots already colonized by another PAC strain, and the power of retention, i.e. the ability of a resident strain of not being suppressed by an invading PAC strain, were calculated for each strain in every combination. The experiment was run twice under two different climatic conditions. Our results show that PAC strains differ (1) in their ability to colonize PAC-free, non-sterile roots, (2) in resistance against being suppressed by another PAC strain and (3) in their ability to invade roots already colonized by another PAC strain. In addition, both the PAC–PAC and the PAC-host interactions depend on the climatic conditions.     

Proteomic analysis of secretion from human transplanted submandibular gland replacing lacrimal gland with severe keratoconjunctivitis sicca

Purpose: Proteomic analysis of secretions from transplanted or non-transplanted submandibular glands in patients with severe keratoconjunctivitis sicca and tears from normal eyes. Experimental design: Secretions from submandibular glands transplanted to replace lacrimal glands and non-transplanted submandibular glands were collected at 1 year from 5 patients with severe keratoconjunctivitis sicca undergoing transplantation, and tears were collected from 3 normal subjects. 2-D electrophoresis (2-DE), then mass spectrometry was used to identify proteins. Western blot analysis was used to confirm protein expression. Results: We identified 34 and 11 distinct proteins in the saliva from transplanted submandibular glands and tears, respectively. The saliva from transplanted submandibular glands contained almost all the proteins abundant in tear fluid. The functions of identified proteins in the saliva from transplanted submandibular gland were mainly immune response and anti-bacterial. In total, 7 proteins showed differential expression between the saliva of transplanted and non-transplanted submandibular glands. The upregulation of short palate, lung and nasal epithelium carcinoma-associated protein 2 and carbonic anhydrase VI was confirmed by Western blot analysis. Conclusions: Identified proteins in saliva from transplanted submandibular glands may protect ocular structures. These findings can help in understanding the functional status of transplanted submandibular glands.     

Developmental potencies of nuclei from cleavage,preblastoderm, and syncytial blastoderm transplanted into unfertilized eggs ofDrosophila melanogaster

Summary Wild-type nuclei from eggs ofDrosophila melanogaster at various developmental stages and from different regions of the egg—cleavage nuclei, pole nuclei from preblastoderm, and lateral nuclei from syncytial blastoderm—were singly implanted into unfertilizedy w sn ³ lz _50e eggs to determine their developmental potencies.All three types of transplanted nuclei were almost equally effective in initiating development of unfertilized eggs. Development was arrested in one of five critieal embryonic stages or in one of the three larval instars. The frequency of individuals reaching a distinct stage was approximately the same for all three types of donor nuclei. The stage-specific pattern of defects was independent of the type of nucleus transplanted.The deviations from normal development were broadly similar to those seen in controls developing from fertilized eggs which had only been punctured or into which cytoplasm had been injected. Many defective embryos also occurred in these control experiments. These and other observations indicate that a large proportion of irregularly developed individuals found after nuclear transfer can be ascribed to loss of egg material, disturbances in the internal organization of the egg during nuclear implantation, and the difficulty the implanted nucleus has in adjusting to the autonomous processes within the egg, such as the formation and migration of cytoplasmic islands.Some of the defective embryos and larvae originating from nuclear transfer were implanted into adult hosts. After culture for 14 days the early embryonic stages had formed several larval structures, and the late embryonic and larval stages had developed all larval organs. The proliferated imaginal primordia of thesein vivo cultured embryos and larvae, as well as the imaginal disks of the third instar larva, were then implanted into larval hosts with which they passed through metamorphosis and differentiated into imaginal structures. All three types of donor nuclei were capable of producing all adult structures derivedin situ from imaginal disks. The phenotype of these structures waswild-type, thus demonstrating their origin from the transplanted nuclei.The problem as to why not all transplanted nuclei initiated development, and why development after nuclear transplantation was arrested at the third larval instar, at the latest, is discussed.This article is dedicated to Professor Friedrich Seidel on the occasion of his 75th birthday.     

Autophagy contributes to regulation of nuclear dynamics during vegetative growth and hyphal fusion in Fusarium oxysporum

In the fungal pathogen Fusarium oxysporum, vegetative hyphal fusion triggers nuclear mitotic division in the invading hypha followed by migration of a nucleus into the receptor hypha and degradation of the resident nucleus. Here we examined the role of autophagy in fusion-induced nuclear degradation. A search of the F. oxysporum genome database for autophagy pathway components identified putative orthologs of 16 core autophagy-related (ATG) genes in yeast, including the ubiquitin-like protein Atg8, which is required for the formation of autophagosomal membranes. F. oxysporum Foatg8Δ mutants were generated in a strain harboring H1-cherry fluorescent protein (ChFP)-labeled nuclei to facilitate analysis of nuclear dynamics. The Foatg8Δ mutants did not show MDC-positive staining in contrast to the wild type and the FoATG8-complemented (cFoATG8) strain, suggesting that FoAtg8 is required for autophagy in F. oxysporum. The Foatg8Δ strains displayed reduced rates of hyphal growth, conidiation, and fusion, and were significantly attenuated in virulence on tomato plants and in the nonvertebrate animal host Galleria mellonella. In contrast to wild-type hyphae, which are almost exclusively composed of uninucleated hyphal compartments, the hyphae of the Foatg8Δ mutants contained a significant fraction of hyphal compartments with 2 or more nuclei. The increase in the number of nuclei per hyphal compartment was particularly evident after hyphal fusion events. Time-lapse microscopy analyses revealed abnormal mitotic patterns during vegetative growth in the Foatg8Δ mutants. Our results suggest that autophagy mediates nuclear degradation after hyphal fusion and has a general function in the control of nuclear distribution in F. oxysporum.     

Some required events in conidial germination of Neurospora crassa.

A temperature-sensitive mutant of Neurospora crassa, with reduced levels of protein synthesis at 37°C, was used to identify some essential events in conidial germination. Conidia of mutant strain psi-1 were incubated for 2 hr at 37°C and then shifted to 20°C. Germination was inhibited at 37°C, but commenced after 1.5 hr at 20°C. Increases in aspartate transcarbamylase activity, cell wall synthesis, and nuclear number preceded germination. However, increases in glutamate dehydrogenase activity, amino acid uptake, and DNA synthesis were inhibited prior to germination. Although all of these events were correlated with germination in control cultures of the mutant at 20°C and of its parent strain at 20 and 37°C, some events were apparently not essential for germination. The requirement for aspartate transcarbamylase activity was demonstrated independently by the failure of strain pyr-3d (lacking the activity) to germinate in the absence of uridine. The dispensability of glutamate dehydrogenase activity and DNA synthesis for the germination of some conidia was verified by the germination of strain am-1 (lacking glutamate dehydrogenase activity) in the absence of glutamate and by the germination of the parent strain in the presence of hydroxyurea (an inhibitor of DNA synthesis). These findings identify some landmarks in germination which may be useful in further studies of the regulation of a developmental program. They also provide preliminary evidence that the resting conidia may contain nuclei arrested at different stages of their division cycle.