A characterization of pH-regulated dimorphism in Candida albicans

When cells of the dimorphic yeast Candida albicans are grown to stationary phase in defined liquid medium at 25°C, they accumulate as singlets in G_l of the cell cycle. When these pluripotent, stationary phase singlets are released into fresh medium at 37°C, they synchronously evaginate after an average period of 135 to 140 minutes and form either buds or mycelia, depending upon the pH of the medium into which they are released. This method of dimorphic regulation offers the distinct advantage of comparability and serves as a very precise method for temporal comparisons of molecular and cytological events related to the establishment of the alternate growth phenotypes. In the present report, we have carefully examined the effects of individually varying pH or temperature on the length of the pre-evagination period, the population synchrony for evagination, and the phenotype of daughter cells. Exact phenotypic transition points, optima, and upper limits are defined for both temperature and pH. In addition, a method of pH-regulated dimorphism is developed in which the original temperature shift is removed from the inductive process. Finally, a common transition phenotype is described for cells reverting from the initial mycelial to budding phenotype when either pH or temperature traverse their respective transition points. The advantages as well as limitations of pH-regulated dimorphism are discussed in detail.     

The temporal regulation of protein synthesis during synchronous bud or mycelium formation in the dimorphic yeast Candida albicans

When stationary phase cells of the dimorphic yeast Candida albicans are diluted into fresh medium at 37°C at either pH 4.5 or pH 6.5, they evaginate at exactly the same time and with the same synchrony. However, they then grow in the budding yeast form at the former pH and in the elongate mycelium form at the latter pH. Three phases of protein synthesis are distinguished for cells forming either buds or mycelia: an initial 50-min period (phase I) during which total cell protein remains constant and the rate of incorporation of labeled amino acid into protein is virtually zero; a second period (phase II) during which there is a slow but constant increase in both total cell protein and the rate of incorporation; and a third period (phase III) during which there is a dramatic increase in both total cell protein and the rate of incorporation. The transition from phase I to phase II occurs at the same time for cells forming either buds or mycelia, but the transition from phase II to phase III occurs 20 to 30 min later in the mycelium than in the bud forming population, the same temporal difference observed for phenotypic commitment. The polypeptides synthesized during phases II and III were first analyzed by one-dimensional polyacrylamide gel electrophoresis. The patterns are similar for the two phenotypes. The major polypeptides synthesized during phase II are also synthesized during phase III, but in addition, a group of at least four new major polypeptides appear during phase III for both phenotypes. The minor polypeptides synthesized during phase III were also compared between the two phenotypes by two-dimensional polyacrylamide gel electrophoresis. The patterns, including roughly 200 distinguishable polypeptides, were similar. The similarities in the patterns of protein synthesis and the delay in the onset of phase III in mycelium forming cells are discussed in terms of phenotypic commitment. From these considerations, alternate hypotheses for the regulation of fungal dimorphism, in particular, and cell divergence, in general, are proposed.     

Filament ring formation in the dimorphic yeast Candida albicans

Stationary phase cultures of Candida albicans inoculated into fresh medium at 37 degrees C synchronously from buds at pH 4.5 and mycelia at pH 6.5. During bud formation, a filament ring forms just under the plasma membrane at the mother cell-bud junction at roughly the time of evagination. A filament ring also forms in mycelium-forming cells, but it appears later than in a budding cell and it is positioned along the elongating mycelium, on the average 2 microns from the mother cell-mycelium junction. Sections of filament rings in early and late budding cells and in mycelia appear similar. Each contains approximately 11 to 12 filaments equidistant from one another and closely associated with the plasma membrane. In both budding and mycelium-forming cells, the filament ring disappears when the primary septum grows inward. The close temporal and spatial association of the filament ring and the subsequent chitin-containing septum suggests a role for the filament ring in septum formation. In addition, a close temporal correlation is demonstrated between filament ring formation and the time at which cells become committed to bud formation at pH 4.5 and mycelium formation at pH 6.5. The temporal and spatial differences in filament ring formation between the two growth forms also suggest a simple model for the positioning of the filament ring.     

Dimorphism-associated changes in intracellular pH of Candida albicans

Intracellular pH (pHi) was monitored during pH-regulated dimorphism of Candida albicans using two different methods: (1) by steady-state distribution of propionic acid and (2) by use of polyene antibiotic, nystatin. There was no significant change in pHi during the first 120 min in either bud- or germ tube-forming populations. However, there was a rapid increase around 135 min which also coincided with the time of evagination. The magnitude of increase in pHi was different in the two populations; being 0.44 and 0.14 pH units in bud- and germ tube-forming populations, respectively. In the two diverging populations, the transient increase in pHi was followed by a rapid drop. The sharp rise in pHi of the population destined to form buds was sensitive to orthovanadate and to the depletion of K+ from the medium while this was not the case with germ tube-forming cells. The results suggest that pHi may play an important role in the phenotypic divergence of C. albicans.     

Dimorphism-associated changes in plasma membrane H+-ATPase activity of Candida albicans

In situ plasma membrane H⁺-ATPase activity was monitored during pH-regulated dimorphism of Candida albicans using permeabilized cells. ATPase activity was found to increase in both the bud and germ tube forming populations at 135 min which coincides with the time of evagination. Upon reaching the terminal phenotype the mycelial form exhibited higher H⁺-ATPase activity as compared to the yeast form. At the time of evagination H⁺-efflux exhibited an increase. K⁺ depletion resulted in attenuated ATPase activity and glucose induced H⁺-efflux. The results demonstrate that ATPase may play a regulatory role in dimorphism of C. albicans and K⁺ acts as a modulator.Abbreviations PM Plasma membrane - pHi intracellular pH - Pi inorganic phosphorus - TET Toluene: Ethanol: Triton X-100     

Dimorphism-associated changes in amino acid transport of Candida albicans

Abstract Amino acid uptake was followed during pH-regulated dimorphism of Candida albicans . It was observed that transport activities of various amino acids differed with the morphological phenotype. The uptake rates of l-alanine , l -phenylalanine and of l -lysine were lower and those of l -methionine were higher in elongated hypha (germ tube), while the rates of glycine, l -glutamic acid and l -proline were similar in bud and hyphal phenotypes. Minimum threshold of amino acids transport activity is required at the time of phenotypic commitment in a diverging population of Candida albicans .     

A comparison of volume growth during bud and mycelium formation in Candida albicans: a single cell analysis

When stationary phase cells of the dimorphic yeast Candida albicans are diluted into fresh medium at pH 4.5 (low pH), they synchronously form ellipsoidal buds, but when diluted into the same medium at pH 6.7 (high pH), they synchronously form elongate mycelia. Using a perfusion chamber to monitor single cells, we have compared the rates of volume growth between budding and mycelium-forming cells. Results are presented which demonstrate that: (1) after release from stationary phase into medium of low or high pH, each original sphere grows in volume to the time of initial evagination, but does not grow subsequently; (2) successive budding on the original mother cell occurs without interruption resulting in continuous volume growth; however, an interruption in volume growth of the initial bud (B1) occurs before it in turn evaginates; and (3) the rate of volume growth of the first bud at low pH is identical to the rate of volume growth of the mycelium at high pH even though the surface to volume ratios are quite different. The last result is unexpected and is therefore considered in relation to cell wall deposition.     

The evolution of sexual size dimorphism in the house finch. III. Developmental basis

Sexual size dimorphism of adults proximately results from a combination of sexually dimorphic growth patterns and selection on growing individuals. Yet, most studies of the evolution of dimorphism have focused on correlates of only adult morphologies. Here we examined the ontogeny of sexual size dimorphism in an isolated population of the house finch (Carpodacus mexicanus). Sexes differed in growth rates and growth duration; in most traits, females grew faster than males, but males grew for a longer period. Sexual dimorphism in bill traits (bill length, width, depth) and in body traits (wing, tarsus, and tail length; mass) developed during different periods of ontogeny. Growth of bill traits was most different between sexes during the juvenile period (after leaving the nest), whereas growth of body traits was most sexually dimorphic during the first few days after hatching. Postgrowth selection on juveniles strongly influenced sexual dimorphism in all traits; in some traits, this selection canceled or reversed dimorphism patterns produced by growth differences between sexes. The net result was that adult sexual dimorphism, to a large degree, was an outcome of selection for survival during juvenile stages. We suggest that previously documented fast and extensive divergence of house finch populations in sexual size dimorphism may be partially produced by distinct environmental conditions during growth in these populations.     

Amino acid uptake as a function of differentiation in Candida albicans: studies of a non-germinative variant

The transport of four amino acids (L-methionine, L-phenylalanine, L-lysine and L-alanine) was studied during pH-regulated dimorphism in Candida albicans and its stable, non-germinative variant. The permeases responsible for uptake responded differently to differentiation and the transport activities varied during the course of morphogenesis. An increase in uptake around the time of evagination was observed in all four amino acids in both the strains studied. The uptake rates of L-methionine and L-phenylalanine were greater in fully differentiated hyphae, while the rate of L-lysine was higher in fully differentiated buds. Uptake rates of L-alanine, however, did not show any morphotypic related variation. The possible implication of these transport activities in relation to differentiation is discussed.     

Molecular collaborations between serpins and trefoil factor promote endodermal cell growth and gastrointestinal differentiation in budding tunicates

We present evidence supporting novel collaborations between the serine protease inhibitor (serpin) and the trefoil factor during the budding stage of the tunicate Polyandrocarpa misakiensis. Using a maltose-binding protein/P-serpin fusion protein, two polypeptides of 40 kDa and 45 kDa were pulled down from Polyandrocarpa homogenates. Based on their partial amino acid sequence data, a single cDNA (928 bp) was cloned. It encodes a polypeptide that has five tandem repeats of a trefoil consensus motif. Thus, we termed the cDNA P-trefoil. Both P-trefoil and P-serpin were expressed exclusively by coelomic cells during budding. P-Trefoil was expressed mainly by coelomic cells throughout the asexual life cycle of Polyandrocarpa, while P-Serpin was localized particularly in coelomic cells and in the extracellular matrix in developing buds. The native P-Trefoil protein showed aminopeptidase activity. It induced cell growth in cultured Polyandrocarpa cells at a concentration of 8 microg/mL. P-Serpin reinforced this activity of P-Trefoil. Further, a mixture of P-Trefoil and P-Serpin exhibited the in vitro induction of a gut-specific alkaline phosphatase. These results show for the first time that a serpin can interact with a trefoil factor to play a role in the cellular growth and differentiation of the gastric epithelium.     

Sexual dimorphism in the andromonoecious Euphorbia nicaeensis: effects of gender and inflorescence development

BACKGROUND AND AIMS: In andromonoecious taxa with separate floral types along the inflorescence, architectural or plastic effects can simulate floral sexual dimorphism. Both the primary and secondary sexual characteristics of the cyathia of the protogynous andromonoecious species Euphorbia nicaeensis were analysed according to their sex and arrangement on the inflorescence. METHODS: The production of male and hermaphrodite cyathia at each inflorescence level was surveyed in two natural populations. The longevity, size, pollen production and viability, and nectar secretion of both types of cyathia were checked between inflorescence levels and between sexes at the only level at which they occur together. This sampling method makes it possible to know whether differences between cyathia types are based on sex or are attributable to inflorescence development. KEY RESULTS: Male cyathia were produced predominantly at the first and second inflorescence levels, whereas at levels 3-5, the cyathia were almost exclusively hermaphrodite. Viable pollen production by male cyathia at the second inflorescence level was higher than that of hermaphrodite cyathia at the third level but, when males and hermaphrodites at the same level were compared, their pollen production was similar. Male and hermaphrodite cyathia were similar in size, irrespective of the inflorescence level, although the exclusively hermaphrodite cyathia of the last level were smaller. Both cyathium types produced similar amounts of sugar. However, male cyathia produced nectar during their whole lifespans, whereas hermaphrodites produced it exclusively during their male phase. Moreover, the nectary activity of male cyathia started earlier in the day than that of hermaphrodites. CONCLUSIONS: An apparent floral dimorphism exists in the primary sexual characteristics of Euphorbia nicaeensis because differences in pollen production between cyathium types are due to theirs positions. Similarly, differences affecting most secondary sexual characteristics are only apparent between the two cyathium types. However, E. nicaeensis shows a true but slight floral dimorphism in some of the secondary sex characters related to nectar secretion. The lack of nectar production by the female phase of the hermaphrodite cyathia of E. nicaeensis indicates that this is a deceit-pollinated species.     

Oscillatory behavior of Saccharomyces cerevisiae in continuous culture: II. Analysis of cell synchronization and metabolism

Sustained oscillations of biomass, ethanol, and ammonium concentrations, specific growth rate, and specific uptake rates of ethanol, ammonium, and oxygen were found in continuous cultures of Saccharomyces cerevisiae under controlled dissolved oxygen (DO), pH, and temperature conditions. The period of oscillations was approximately 2.5-3 h at a pH of 5.5 and 2-2.5 h at a pH of 6.5. Oscillations were observed only under conditions of low carbon (glucose below the minimum detectable level), nitrogen nutrient (ammonium concentration varied between 0.00001 and 0.0015M), and ethanol concentration (0.002-0.085 g/L) in the bioreactor.The oscillatory behavior at pH 5.5 was also characterized by partially synchronized cell growth and reproduction. Not only did the total percentage of budding cells oscillate with the same period as observed for the global biomass and nutrient concentrations, but the peaks in the individual subpopulations of initial budding, middle budding, and late budding cells appeared sequentially during the oscillation period. This provides strong evidence of the hypothesis that variations in metabolism during different periods in the cell cycle of a partially synchronized cell population are responsible for the observed oscillatory bioreactor behavior.The specific nutrient uptake rates for ammonium and oxygen as well as the net specific ethanol uptake rate oscillated with the same period as the biomass oscillations. These results show a dramatic increase in the ammonium and oxygen consumption rates prior to the initial budding of the synchronized subpopulation and a decrease in these rates during the late budding phase. At a pH of 5.5, the late budding phase is characterized by high specific ethanol productivity; however, the ethanol productivity lags the late budding phase at a pH pf 6.5. The observed time-varying metabolism in the oscillatory operating regime appears to be the result of the metabolic changes which occur during the cell cycle. Models which can predict the oscillatory biomass concentration and nutrient levels in this regime must be capable of predicting the concentrations and metabolic rates of the subpopulations as well.     

Field and laboratory investigations of budding in the tetillid sponge Cinachyrella cavernosa

The budding process of the tetillid sponge Cinachyrella cavernosa was studied for one year in the low intertidal zone near Mhapan (15°55′27.48″N, 73°33′29.89″E), on the central west coast of India. The sponges showed the highest budding frequency when the average water temperature of intertidal rock pools was 32.4±0.23°C (February–March), followed by a significant decrease in budding frequency at 28.2±0.12°C (April–July), and no budding at ≤25.9±0.12°C (August–November). Stepwise multiple regression analysis of physico‐chemical factors revealed temperature as the most prominent factor regulating the intensity of budding. Based on size and morphology, three stages of sponge buds were defined. The production of buds was found to be asynchronous, as adult sponges possessed buds of all three stages. Differences among these stages were examined at ultrastructural (in terms of spicules) and molecular (in terms of RNA/DNA) levels. Stage I (<0.5 mm dia‐meter) buds showed a complete absence of microscleres (sigmaspires), whereas stage II (0.5–1 mm) and stage III (>1 mm) buds contained all spicules characteristic of the adult sponge. There was a significant increase in RNA/DNA ratio from stage I to III, suggestive of a progressive increase in physiological activity during the developmental process. Additionally, we studied post‐settlement bud growth under field and laboratory conditions. Newly settled buds displayed a lower average‐specific growth rate in the field, owing to variability in environmental conditions, but more rapid growth under controlled conditions in the laboratory. This study highlights the role of abiotic factors in regulating the budding process and stresses the ecological significance of budding in maintaining natural sponge populations. Our data suggest that an increased frequency of budding under stressful conditions, such as high temperature, is an advantageous adaptation for these sponges. Buds showed rapid development, as no metamorphosis is involved, and retained the genotype of the parents, yielding high reproductive outputs and survival rates.     

Regulation of protein synthesis during the preaggregative period of Dictyostelium discoideum development: involvement of close cell associations and cAMP

The preaggregative period of Dictyostelium discoideum is composed of two rate-limiting components which exhibit dramatic differences in either their dependency upon, or sensitivity to, close cell-cell associations, inhibitors of protein synthesis, temperature, and pH. The first component comprises the initial 4.5 hr and the second component the last 2.5 hr of the preaggregative period. By pulse-labeling cells with [35S]methionine, separating polypeptides by 2D-PAGE, and semiquantitatively comparing the rates of synthesis of 778 individual polypeptides by fluorography, the following results were obtained: a detailed program of protein synthesis accompanies the preaggregative (0-7 hr) and aggregative (7-10.5 hr) periods of development; this includes significant decreases in the rate of synthesis of 93 polypeptides synthesized during vegetative growth and significant increases in the rate of synthesis of 74 polypeptides either undetectable or synthesized at relatively low rates during vegetative growth; 35 polypeptides are transiently synthesized at different times during the preaggregative and aggregative periods; two peaks of activity are clearly defined for both increases and decreases; these peaks correlate temporally with the first and second rate-limiting components of the preaggregative period; the majority of changes (74%) which occur during the first rate-limiting component will occur in the absence of close cell-cell associations, but the majority (66%) which normally occur during the second rate-limiting component do not occur in the absence of close cell-cell associations; a high concentration of cAMP in the medium of continuous suspension cultures does not stimulate most of the changes which are dependent upon close cell-cell associations; even though cAMP stimulates progress through the second rate-limiting component in suspension cultures first allowed to associate for 4.5 hr ("competent" cells) prior to disaggregation it still does not stimulate most of the changes which are dependent upon close cell-cell associations; and synthesis of only 3 out of 778 polypeptides appears to be stimulated by addition of exogenous cAMP, and only in resuspended cultures of "competent" cells. The prominent role of close cell-cell association and the surprisingly minor effect of cAMP in the regulation of the program of protein synthesis accompanying the preaggregative and aggregative periods of Dictyostelium are discussed, especially as they relate to the effect of cAMP on protein synthesis in suspended cultures of postaggregative cells.     

ANALYSIS OF POLYPEPTIDES ASSOCIATED WITH SHOOT FORMATION IN TOBACCO CALLUS CULTURES

Callus lines of Nicotiana tabacum were selected for competence and lack of competence in shoot formation. Changes in total and chromosomal polypeptides in these shoot-forming and nonshoot-forming tobacco cultures were examined by twodimensional polyacrylamide gel electrophoresis. Qualitative and quantitative differences in total, nonhistone chromosomal, and basic chromosomal polypeptides were evident throughout the 7-d test period. The analysis of total proteins identified polypeptides specific to shoot-forming and nonshoot-forming tissue during the 7-d sampling period. A small number of basic chromosomal proteins were found solely in shoot-forming or nonshoot-forming tissue. One basic chromosomal protein was detected in only nonshoot-forming tissue at all sampling times. Two proteins, although present in shoot-forming tissue, were present at elevated levels in the nonshoot-forming cultures. No temporal changes in basic proteins over the 7-d incubation period were observed. Qualitative differences in total nonhistone chromosomal polypeptides in the shoot-forming and nonshoot-forming tissue were also observed. Differences in chromosomal polypeptides were observed. In contrast to the basic chromosomal proteins, temporal variation in the nonhistone chromosomal polypeptides was demonstrated. Throughout the 7-d sampling period, 29 and 12 nonhistone chromosomal polypeptides varied qualitatively in shoot-forming and nonshoot-forming callus cultures, respectively. In vitro labeling with ³²P-orthophosphate indicated that approximately 1.0% and 0.3% of the nonhistone chromosomal proteins were phosphorylated in the shoot-forming and nonshoot-forming cultures. Of these phosphorylated polypeptides, one was present in nonshoot-forming tissue and three were detected only in the shoot-forming tissue. Phosphorylation occurred at serine or threonine residues.     

Morphology-related effects on gene expression and protein accumulation of the yeast Arxula adeninivorans LS3

The dimorphism of the yeast Arxula adeninivorans LS3 is regulated by cultivation temperatures. Up to 42 degrees C the yeast grows as budding cells, which turn to mycelia at higher temperatures. To test whether the dimorphism is exclusively induced by high temperatures or also by other conditions, mutants were selected with an altered behaviour with respect to dimorphism. After mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine, five of 25,000 colonies formed a very rough surface consisting of mycelia at 30 degrees C, in contrast to the wild-type. These mutants allow temperature-mediated and morphology-related effects on gene expression and protein accumulation to be distinguished. Budding cells and mycelia showed different expression of genes encoding secretory proteins at the same temperature. Mycelia secreted two-fold more protein than budding cells, including the enzymes glucoamylase and invertase. This indicated that morphology, rather than temperature, is the decisive factor in the analysed processes.     

Effect of glucose starvation on germ-tube production byCandida albicans

By incubating starved and unstarved yeast cells in synthetic media with a pH of 4.5 or 6.7 at 37°C the effect of a 3 hours' glucose starvation on germ-tube production byCandida albicans was evaluated. In addition the endocellular content of total carbohydrates, glycogen, trehalose and proteins after and before the starvation were dosed. The most interesting result was the overcoming of the pH-regulated dimorphism, thanks to the starvation treatment. Infact the starved cultures produced germtubes indifferently in neutral or acid media, whereas the filamentation of the unstarved cultures was more copious in pH 6.7 medium. The endocellular content of trehalose and protein was unchanged, whereas total carbohydrates and glycogen showed a shortage after the 3 hours' glucose starvation. The possible involvements of these metabolic changes in the regulation of dimorphic transition are discussed.     

Responses of Rhodotorula mucilaginosa under Pb(II) stress: carotenoid production and budding

Rhodotorula mucilaginosa resists heavy metal (HM) stress because of its abundant extracellular polymeric substances and functional vesicles. In this study, we provided new insights into its survival strategies at both biochemical and genetic levels. After lead exposure, carotenoid biosynthesis was initiated within 24 h incubation and then increased to the maximum after 96 h of incubation. Raman analysis confirmed that carotenoids (primarily β-carotene) were the major identifiable chemical substances on the cell surface. Moreover, the increased carotenoid production was accompanied by a rising budding rate, ~40% higher than that in the cultures without Pb. During the 96 h of incubation, the driving force for Pb accumulation was assigned to this elevated budding rate. After 96 h, biosorption was primarily attributed to the enhanced antioxidant ability of the single cells during carotenoid production. Furthermore, the yeast budding cells demonstrated an evidently heterogeneous biosorption of Pb, i.e., the rejuvenated daughters had a relatively lower Pb level than the mother cells. This resulted in the protection of the buds from Pb stress. After investigating phosphorus uptake and the RNA sequencing data, we finally confirmed two tightly correlated pathways that resist HM stress, i.e., biochemical (carotenoid production) and reproductive (healthy buds) pathways.     

棉田绿盲蝽种群密度的调查方法

本文比较研究了棉田绿盲蝽Apolygus lucorum(Meyer-Dür)种群的调查方法。全株调查法中,目测法调查到的绿盲蝽种群密度最高,显著高于扫网法和盆拍法。局部调查法发现,蕾上的绿盲蝽种群数量显著高于叶片和花上;蕾上种群数量与整株密度之间呈显著正相关关系(y=1.18 x+3.69)。间接调查法表明:在苗期和蕾期,叶片受害等级和绿盲蝽种群密度之间呈显著正相关关系(苗期:y=25.28 x+8.20;蕾期:y=43.99 x+27.58)。     

Selective Entrapment of Extrachromosomally Amplified DNA by Nuclear Budding and Micronucleation during S Phase

Acentric, autonomously replicating extrachromosomal structures called double-minute chromosomes (DMs) frequently mediate oncogene amplification in human tumors. We show that DMs can be removed from the nucleus by a novel micronucleation mechanism that is initiated by budding of the nuclear membrane during S phase. DMs containing c-myc oncogenes in a colon cancer cell line localized to and replicated at the nuclear periphery. Replication inhibitors increased micronucleation; cell synchronization and bromodeoxyuridine–pulse labeling demonstrated de novo formation of buds and micronuclei during S phase. The frequencies of S-phase nuclear budding and micronucleation were increased dramatically in normal human cells by inactivating p53, suggesting that an S-phase function of p53 minimizes the probability of producing the broken chromosome fragments that induce budding and micronucleation. These data have implications for understanding the behavior of acentric DNA in interphase nuclei and for developing chemotherapeutic strategies based on this new mechanism for DM elimination.