The <i>Cryptococcus neoformans</i> Rim101 Transcription Factor Directly Regulates Genes Required for Adaptation to the Host

O’Meara, Teresa R.; Xu, Wenjie; Selvig, Kyla; O’Meara, Matthew J.; Mitchell, Aaron P.; Alspaugh, J. Andrew

doi:10.1128/mcb.01359-13

Cited by 83 publications

(83 citation statements)

References 69 publications

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“…S3; Supplemental File 5). Previously, binding specificity was known for only 2 TFs in Cryptococcus (Chun et al 2011;O'Meara et al 2014), both of which strongly support our independently derived PWMs.…”

Section: Netprophet Predicts Functional Direct Binding Of Tfs To Thesupporting

confidence: 55%

Model-driven mapping of transcriptional networks reveals the circuitry and dynamics of virulence regulation

et al. 2015

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Key steps in understanding a biological process include identifying genes that are involved and determining how they are regulated. We developed a novel method for identifying transcription factors (TFs) involved in a specific process and used it to map regulation of the key virulence factor of a deadly fungus-its capsule. The map, built from expression profiles of 41 TF mutants, includes 20 TFs not previously known to regulate virulence attributes. It also reveals a hierarchy comprising executive, midlevel, and "foreman" TFs. When grouped by temporal expression pattern, these TFs explain much of the transcriptional dynamics of capsule induction. Phenotypic analysis of TF deletion mutants revealed complex relationships among virulence factors and virulence in mice. These resources and analyses provide the first integrated, systems-level view of capsule regulation and biosynthesis. Our methods dramatically improve the efficiency with which transcriptional networks can be analyzed, making genomic approaches accessible to laboratories focused on specific physiological processes.[Supplemental material is available for this article.]In this paper we present an efficient means of comprehensively mapping the network of transcription factors (TFs) that regulate a particular physiological process. Our approach cycles through deletion of TFs, expression profiling of TF mutants, model construction, and model-directed selection of TFs for the next round of deletion. This predictive genetics approach identifies TFs that affect the process of interest, providing a valuable complement to undirected mutagenesis and screening. Simultaneously, it builds a network model that explains how the TFs affect the process, yielding novel insights into the biological system under study.Mapping the network that regulates a specific process requires knowing which TFs affect that process. One way to identify such TFs is to screen comprehensive mutant libraries, but generating such libraries is not always feasible. Furthermore, genome-scale screening assays must be fast and scalable; such assays may not exist for the process of interest or may be less sensitive than other, more laborious assays. An alternative approach is to map the targets of all TFs encoded in a genome by using methods such as chromatin-immunoprecipitation (ChIP) or large-scale TF deletion and expression analysis. However, undirected, genome-wide approaches are costly and inefficient for probing a specific biological process in detail. We report a model-guided approach that addresses all of these problems by focusing experimental effort on the TFs most likely to be involved in the process of interest. Furthermore, our approach generates a network that provides mechanistic explanations for the phenotypes of TF deletion mutants.Our approach alternates network building by using an algorithm we call NetProphet with identifying relevant TFs by using an algorithm we call PhenoProphet. NetProphet is a validated method for mapping direct, functional regulation that significantly out...

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Section: Netprophet Predicts Functional Direct Binding Of Tfs To Thesupporting

confidence: 55%

Model-driven mapping of transcriptional networks reveals the circuitry and dynamics of virulence regulation

et al. 2015

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“…For the C. albicans Bcr1 and Rim101 transcription factors, prior studies indicate that in vitro and in vivo profiles are fairly divergent (38,39). For Cryptococcus neoformans Rim101 and A. fumigatus SrbA, it appears that the in vivo and in vitro profiles of null mutants are fairly similar (32,40). We can now add A. fumigatus AcuM and AcuK to the group of transcription factors with divergent in vivo and in vitro mutant profiles.…”

Section: Discussionmentioning

confidence: 97%

Divergent Targets of Aspergillus fumigatus AcuK and AcuM Transcription Factors during Growth In Vitro versus Invasive Disease

Pongpom

Liu

et al. 2015

Infect Immun

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eIn Aspergillus nidulans, the AcuK and AcuM transcription factors form a complex that regulates gluconeogenesis. In Aspergillus fumigatus, AcuM governs gluconeogenesis and iron acquisition in vitro and virulence in immunosuppressed mice. However, the function of AcuK was previously unknown. Through in vitro studies, we found that A. fumigatus ⌬acuK single and ⌬acuK ⌬acuM double mutants had impaired gluconeogenesis and iron acquisition, similar to the ⌬acuM mutant. Also, the ⌬acuK, ⌬acuM, and ⌬acuK ⌬acuM mutants had similar virulence defects in mice. However, the ⌬acuK mutant had a milder defect in extracellular siderophore activity and induction of epithelial cell damage in vitro than did the ⌬acuM mutant. Moreover, overexpression of acuM in the ⌬acuK mutant altered expression of 3 genes and partially restored growth under iron-limited conditions, suggesting that AcuM can govern some genes independently of AcuK. Although the ⌬acuK and ⌬acuM mutants had very similar transcriptional profiles in vitro, their transcriptional profiles during murine pulmonary infection differed both from their in vitro profiles and from each other. While AcuK and AcuM governed the expression of only a few iron-responsive genes in vivo, they influenced the expression of other virulence-related genes, such as hexA and dvrA. Therefore, in A. fumigatus, while AcuK and AcuM likely function as part of the same complex, they can also function independently of each other. Furthermore, AcuK and AcuM have different target genes in vivo than in vitro, suggesting that in vivo infection stimulates unique transcriptional regulatory pathways in A. fumigatus. Aspergillus fumigatus causes a variety of diseases, including allergic bronchopulmonary aspergillosis, aspergilloma, invasive pulmonary aspergillosis, and hematogenously disseminated aspergillosis (1, 2). The incidence of invasive aspergillosis is rising due to the increasing number of immunocompromised patients, who are at risk for this disease (3, 4). Furthermore, because invasive aspergillosis remains difficult to diagnose and treat, this infection is still associated with significant mortality (5). One approach to developing new strategies to treat this frequently deadly infection is to target the factors that enable A. fumigatus to survive and proliferate within the host.Iron is an essential trace element for most living organisms, including pathogenic microorganisms. Consequently, sequestration of free iron by the host is a key factor for inhibiting the virulence of microbial pathogens (6-8). Furthermore, most successful pathogens have evolved mechanisms to obtain iron while inside the host. For example, A. fumigatus acquires iron from the host by both reductive iron assimilation and secretion of siderophores (9-11). Siderophore secretion is more important for growth within the host, because A. fumigatus mutants with defects in siderophore synthesis have dramatically attenuated virulence, whereas those with defects in reductive iron assimilation do not (11-13).Previously, we determined tha...

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“…(b) C57BL/6 mice were intranasally infected with H99 or ctr4D::NEO cells for 7 days. RNA was isolated as described previously 30 . Real-time PCR was performed to detect CTR1, CTR4, CMT1, CMT2 and ACT1.…”

Section: Resultsmentioning

confidence: 99%

“…However, recent work has demonstrated that Cuf1 activates both the Cu-detoxification machinery and the Cu-acquisition machinery, in response to high or low Cu conditions, respectively 12 . Moreover, although C. neoformans senses high Cu in the lung and Cu-detoxification genes are critical for fungal survival in the lung, CTR4 is still expressed in the lung at relatively low levels 5,18,30 .…”

Section: Discussionmentioning

confidence: 99%

“…One microgram of total RNA was used for cDNA synthesis, using the GoScript Reverse Transcription System (A5001, Promega), and real-time PCR was performed using a CFX Connect Thermocycler (Bio-rad) as previously described 5 . RNA was isolated from mice infected with C. neoformans as previously described 30 . Briefly, infected lung tissues were first cut into small pieces and resuspended in TRIzol reagent.…”

Section: Methodsmentioning

confidence: 99%

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Reciprocal functions of Cryptococcus neoformans copper homeostasis machinery during pulmonary infection and meningoencephalitis

et al. 2014

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The Cryptococcus neoformans Rim101 Transcription Factor Directly Regulates Genes Required for Adaptation to the Host

Cited by 83 publications

References 69 publications

Model-driven mapping of transcriptional networks reveals the circuitry and dynamics of virulence regulation

Model-driven mapping of transcriptional networks reveals the circuitry and dynamics of virulence regulation

Divergent Targets of Aspergillus fumigatus AcuK and AcuM Transcription Factors during Growth In Vitro versus Invasive Disease

Reciprocal functions of Cryptococcus neoformans copper homeostasis machinery during pulmonary infection and meningoencephalitis

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