"White-opaque transition": a second high-frequency switching system in Candida albicans

A second high-frequency switching system was identified in selected pathogenic strains in the dimorphic yeast Candida albicans. In the characterized strain WO-1, cells switched heritably, reversibly, and at a high frequency (approximately 10(-2] between two phenotypes readily distinguishable by the size, shape, and color of colonies formed on agar at 25 degrees C. In this system, referred to as the "white-opaque transition," cells formed either "white" hemispherical colonies, which were similar to the ones formed by standard laboratory strains of C. albicans, or "opaque" colonies, which were larger, flatter, and grey. At least three other heritable colony phenotypes were generated by WO-1 and included one irregular-wrinkle and two fuzzy colony phenotypes. The basis of the white-opaque transition appears to be a fundamental difference in cellular morphology. White cells were similar in shape, size, and budding pattern to cells of common laboratory strains. In dramatic contrast, opaque cells were bean shaped and exhibited three times the volume and twice the mass of white cells, even though these alternative phenotypes contained the same amount of DNA and a single nucleus in the log phase. In addition to differences in morphology, white and opaque cells differed in their generation time, in their sensitivity to low and high temperatures, and in their capacity to form hypae. The possible molecular mechanisms involved in high-frequency switching in the white-opaque transition are considered.     

Unique phenotype of opaque cells in the white-opaque transition of Candida albicans.

Select strains of Candida albicans switch reversibly and at extremely high frequency between a white and an opaque colony-forming phenotype, which has been referred to as the white-opaque transition. Cells in the white phase exhibit a cellular phenotype indistinguishable from that of most standard strains of C. albicans, but cells in the opaque phase exhibit an unusually large, elongate cellular shape. In comparing the white and opaque cellular phenotypes, the following findings are demonstrated. (i) The surface of the cell wall of maturing opaque cells when viewed by scanning electron microscopy exhibits a unique pimpled, or punctate, pattern not observed in white cells or standard strains of C. albicans. (ii) The dynamics of actin localization which accompanies opaque-cell growth first follows the pattern of budding cells during early opaque-bud growth and then the pattern of hypha-forming cells during late opaque-bud growth. (iii) A hypha-specific cell surface antigen is also expressed on the surface of opaque budding cells. (iv) An opaque-specific surface antigen is distributed in a punctate pattern.     

Dosage of the smallest chromosome affects both the yeast-hyphal transition and the white-opaque transition of Candida albicans WO-1.

The WO-1 strain of Candida albicans is capable of alternating between two highly distinct yeast cell types termed white and opaque (E. H. A. Rikkerrink, B. B. Magee, and P. T. Magee, J. Bacteriol. 170:895-899, 1988; B. Slutsky, M. Staebell, J. Anderson, L. Risen, M. Pfaller, and D. R. Soll, J. Bacteriol. 169:189-197, 1987). We have isolated WO-1 mutants that show a marked deficiency at being able to switch from the white form to the opaque form under conditions normally favorable for this transition. Pulsed-field electrophoresis demonstrated that one of the initial two spontaneous nonswitching mutants lacked the smallest chromosome that is normally present in WO-1. The availability of a WO-1 derivative whose only functional ADE2 gene is located on this small chromosome made possible, through the induction of chromosome nondisjunction, the isolation of numerous new mutants missing this chromosome as well as mutants containing two copies of the chromosome. Mutants missing the smallest chromosome showed a greatly diminished ability to produce opaque sectors and to produce germ tubes in the presence of human serum. Mutants containing two copies of the small chromosome showed an increased ability to produce germ tubes. These results indicate that this small chromosome carries one or more genes involved in both the white-opaque switch and the yeast-hyphal switch.     

White-Opaque Switching of Candida albicans Allows Immune Evasion in an Environment-Dependent Fashion

Candida albicans strains that are homozygous at the mating type locus can spontaneously and reversibly switch from the normal yeast morphology (white) to an elongated cell type (opaque), which is the mating-competent form of the fungus. White-opaque switching also influences the ability of C. albicans to colonize and proliferate in specific host niches and its susceptibility to host defense mechanisms. We used live imaging to observe the interaction of white and opaque cells with host phagocytic cells. For this purpose, we generated derivatives of the switching-competent strain WO-1 that express green fluorescent protein from a white-specific promoter and red fluorescent protein from an opaque-specific promoter or vice versa. When mixed populations of these differentially labeled white and opaque cells were incubated with human polymorphonuclear neutrophils (PMNs) on a glass slide, the neutrophils selectively phagocytosed and killed white cells, despite frequent physical interaction with opaque cells. White cells were attacked only after they started to form a germ tube, indicating that the suppression of filamentation in opaque cells saved them from recognition by the PMNs. In contrast to neutrophils, dendritic cells internalized white as well as opaque cells. However, when embedded in a collagen matrix, the PMNs also phagocytosed both white and opaque cells with similar efficiency. These results suggest that, depending on the environment, white-opaque switching enables C. albicans to escape from specific host defense mechanisms.     

TOS9 regulates white-opaque switching in Candida albicans

In Candida albicans, the a1-alpha2 complex represses white-opaque switching, as well as mating. Based upon the assumption that the a1-alpha2 corepressor complex binds to the gene that regulates white-opaque switching, a chromatinimmunoprecipitation-microarray analysis strategy was used to identify 52 genes that bound to the complex. One of these genes, TOS9, exhibited an expression pattern consistent with a "master switch gene." TOS9 was only expressed in opaque cells, and its gene product, Tos9p, localized to the nucleus. Deletion of the gene blocked cells in the white phase, misexpression in the white phase caused stable mass conversion of cells to the opaque state, and misexpression blocked temperature-induced mass conversion from the opaque state to the white state. A model was developed for the regulation of spontaneous switching between the opaque state and the white state that includes stochastic changes of Tos9p levels above and below a threshold that induce changes in the chromatin state of an as-yet-unidentified switching locus. TOS9 has also been referred to as EAP2 and WOR1.     

Candida albicans MTLalpha tup1Delta mutants can reversibly switch to mating-competent, filamentous growth forms

Candida albicans strains that are homozygous at the mating type locus (MTLa or MTLalpha) can spontaneously switch from the normal round-to-oval yeast cell morphology to an elongated, so-called opaque cell form that can mate with opaque cells of the opposite mating type. In response to environmental signals, C. albicans also undergoes a transition from yeast to filamentous growth, which is negatively regulated by the general repressor Tup1p. Therefore, C. albicans mutants in which the TUP1 gene is inactivated grow constitutively in the filamentous form. We found that tup1Delta mutants of the MTLalpha strain WO-1 are still able to undergo phenotypic switching. Although the mutants had lost the capacity to grow in the normal yeast (white) or opaque forms, they could still reversibly switch between four different cell and colony phenotypes (designated as fuzzy, frizzy, wrinkled and smooth) at a frequency of about 10(-3) to 10(-4). Deletion of TUP1 resulted in deregulated expression of phase-specific genes. While the white-specific WH11 gene was constitutively expressed in all four cell types, the opaque-specific SAP1 gene remained repressed and the opaque-specific OP4 gene was weakly induced in all phase variants. In spite of the loss of white- and opaque-specific cell morphology and gene expression, the tup1Delta mutants retained an important characteristic of their wild-type parent, the ability to switch to a mating-competent form. The three filamentous phase variants (fuzzy, frizzy and wrinkled) all were able to mate and produce recombinant progeny with opaque cells of an MTLa strain at frequencies that were somewhat lower than those of normal opaque cells, whereas the smooth phase variant was unable to do so. Therefore, although deletion of TUP1 in C. albicans MTLalpha cells affects cellular morphology and gene expression patterns, the mutants can still reversibly switch between mating-competent and -incompetent cell types and mate with a partner of the opposite mating type.     

近平滑念珠菌的形态转换观察

目的观察近平滑念珠菌在不同培养基的形态转换现象,以及温度对其形态转换的影响。方法收集近平滑念珠菌正常人皮肤携带株及临床致病株和标准株,接种于改良Lee培养基和含桃红B的YPD培养基,观察其不同形态转换,以及温度变化对光滑(W)与皱褶(O)形态转换的影响。结果近平滑念珠菌在Lee培养基和含桃红B的YPD培养基上,均可以出现多种形态以及一定频率W-O转换现象。在观察W向O形态转换过程中发现,与25℃培养温度相比,37℃条件下光滑菌落形态占更多的比例。结论近平滑念珠菌体外培养时存在形态转换及W-O转换现象,且于37℃时更易保持光滑形态。含桃红B的YPD培养基也可以用于基本的W-O形态转换观察。     

Opaque cells signal white cells to form biofilms in Candida albicans

Upon homozygosis from a/alpha to a/a or alpha/alpha, Candida albicans must still switch from the 'white' to 'opaque' phenotype to mate. It was, therefore, surprising to discover that pheromone selectively upregulated mating-associated genes in mating-incompetent white cells without causing G1 arrest or shmoo formation. White cells, like opaque cells, possess pheromone receptors, although their distribution and redistribution upon pheromone treatment differ between the two cell types. In speculating about the possible role of the white cell pheromone response, it is hypothesized that in overlapping white a/a and alpha/alpha populations in nature, rare opaque cells, through the release of pheromone, signal majority white cells of opposite mating type to form a biofilm that facilitates mating. In support of this hypothesis, it is demonstrated that pheromone induces cohesiveness between white cells, minority opaque cells increase two-fold the thickness of majority white cell biofilms, and majority white cell biofilms facilitate minority opaque cell chemotropism. These results reveal a novel form of communication between switch phenotypes, analogous to the inductive events during embryogenesis in higher eukaryotes.     

The White Cell Response to Pheromone Is a General Characteristic of Candida albicans Strains

For Candida albicans, evidence has suggested that the mating pheromones activate not only the mating response in mating-competent opaque cells but also a unique response in mating-incompetent white cells that includes increased cohesion and adhesion, enhanced biofilm formation, and expression of select mating-related and white cell-specific genes. On the basis of a recent microarray analysis comparing changes in the global expression patterns of white cells in two strains in response to α-pheromone, however, skepticism concerning the validity and generality of the white cell response has been voiced. Here, we present evidence that the response occurs in all tested media (Lee's, RPMI, SpiderM, yeast extract-peptone-dextrose, and a synthetic medium) and in all of the 27 tested strains, including a/a and α/α strains, derivatives of the common laboratory strain SC5314, and representatives from all of the five major clades. The white cell response to pheromone is therefore a general characteristic of MTL-homozygous strains of C. albicans.     

The white-phase-specific gene<Emphasis Type="Italic"> WH11</Emphasis> is not required for white-opaque switching in<Emphasis Type="Italic"> Candida albicans</Emphasis>

Phenotypic switching between white and opaque cells is important for adaptation to different host environments and for mating in the opportunistic fungal pathogen Candida albicans. Genes that are specifically activated in one of the two cell types are likely to be important for their phenotypic characteristics. The WH11 gene is a white-phase-specific gene that has been suggested to be involved in the maintenance of the white-phase phenotype. To elucidate the role of WH11 in white-opaque switching, we constructed mutants of the C. albicans strain WO-1 in which the WH11 gene was deleted. The wh11 mutants were still able to form both white and opaque cells whose cellular and colony phenotypes were indistinguishable from those of the wild type. Deletion of WH11 also did not affect the activation and deactivation of the white-phase-specific WH11 promoter and the opaque-phase-specific OP4 and SAP1 promoters in the appropriate cell type. Finally, switching from the white to the opaque phase and vice versa occurred with the same frequency in wild-type and wh11 mutants. Therefore, the WH11 gene is not required for phenotypic switching, and its protein product seems to have other roles in white cells, which are dispensable after the switch to the opaque phase.Communicated by E. Cerdá-Olmedo