Andrew G. Tag scite author profile

Light signaling pathways and circadian clocks are inextricably linked and have profound effects on behavior in most organisms. Here, we used chromatin immunoprecipitation (ChIP) sequencing to uncover direct targets of the Neurospora crassa circadian regulator White Collar Complex (WCC). The WCC is a blue-light receptor and the key transcription factor of the circadian oscillator. It controls a transcriptional network that regulates ϳ20% of all genes, generating daily rhythms and responses to light. We found that in response to light, WCC binds to hundreds of genomic regions, including the promoters of previously identified clock-and lightregulated genes. We show that WCC directly controls the expression of 24 transcription factor genes, including the clock-controlled adv-1 gene, which controls a circadian output pathway required for daily rhythms in development. Our findings provide links between the key circadian activator and effectors in downstream regulatory pathways.

show abstract

A Novel Regulatory Gene, Tri10 , Controls Trichothecene Toxin Production and Gene Expression

Tag¹,

Garifullina²,

Peplow³

et al. 2001

Appl Environ Microbiol

110

107

View full text Add to dashboard Cite

We report here the characterization of Tri10, a novel regulatory gene within the trichothecene gene cluster. Comparison of Tri10 genomic and mRNA sequences revealed that removal of a single 77-bp intron provided a 1,260-bp open reading frame, encoding a 420-amino-acid protein. Disruption of Tri10 in Fusarium sporotrichioides abolished T-2 toxin production and dramatically decreased the transcript accumulation for four trichothecene genes (Tri4, Tri5, Tri6, and Tri101) and an apparent farnesyl pyrophosphate synthetase (Fpps) gene. Conversely, homologous integration of a disruption vector by a single upstream crossover event significantly increased T-2 toxin production and elevated the transcript accumulation of the trichothecene genes and Fpps. Further analysis revealed that disruption of Tri10, and to a greater extent the disruption of Tri6, increased sensitivity to T-2 toxin under certain growth conditions. Although Tri10 is conserved in Fusarium graminearum and Fusarium sambucinum and clearly plays a central role in regulating trichothecene gene expression, it does not show any significant matches to proteins of known or predicted function or to motifs except a single transmembrane domain. We suggest a model in which Tri10 acts upstream of the clusterencoded transcription factor TRI6 and is necessary for full expression of both the other trichothecene genes and the genes for the primary metabolic pathway that precedes the trichothecene biosynthetic pathway, as well as for wild-type levels of trichothecene self-protection. We further suggest the presence of a regulatory loop where Tri6 is not required for the transcription of Tri10 but is required to limit the expression of Tri10.The trichothecenes represent a large family of toxic secondary metabolites produced by a variety of filamentous fungi, including Fusarium, Myrothecium, Stachybotrys, Trichoderma, and Trichothecium (16). They are primarily found as contaminants in food and animal feed, and consumption of these compounds by humans or livestock results in vomiting, alimentary hemorrhaging, and dermatitis (20). These toxins are potent inhibitors of eukaryotic protein synthesis (23) and induce apoptosis (24). In plants the trichothecenes are also phytotoxic and have been associated with virulence in specific plantpathogen interactions (8,9,12,25).

show abstract

G‐protein signalling mediates differential production of toxic secondary metabolites

Tag¹,

Hicks²,

Garifullina³

et al. 2000

Molecular Microbiology

115

View full text Add to dashboard Cite

Filamentous fungi elaborate a complex array of secondary metabolites, including antibiotics and mycotoxins. As many of these compounds pose significant economic and health concerns, elucidation of the underlying cellular mechanisms that control their production is essential. Previous work revealed that synthesis of the carcinogenic mycotoxins sterigmatocystin (ST) and aflatoxin (AF) in Aspergillus species is negatively controlled by FadA, the α‐subunit of a heterotrimeric G‐protein. In sharp contrast, we show here that the dominant activating fadA allele, fadAG42R, stimulates transcription of a gene from the A. nidulans penicillin (PN) gene cluster and elevates penicillin production. Thus, FadA has opposite roles in regulating the biosynthesis of a potent antibiotic (PN) and a lethal mycotoxin (ST) in A. nidulans. Furthermore, expression of fadAG42R in Fusarium sporotrichioides increases trichothecene (TR) mycotoxin production and alters TR gene expression. Our findings reveal that a G‐protein defines an important control point for differential expression of fungal secondary metabolites within and across fungal genera. These data provide critical evidence suggesting that targeting G‐protein signal transduction pathways as a means of controlling or preventing the production of a single mycotoxin could have serious undesirable consequences with regard to the production of other secondary metabolites.

show abstract

Identification of New Genes Positively Regulated by Tri10 and a Regulatory Network for Trichothecene Mycotoxin Production

Peplow

Tag

Garifullina

et al. 2003

Appl Environ Microbiol

View full text Add to dashboard Cite

Tri10, a regulatory gene in trichothecene mycotoxin-producing Fusarium species, is required for trichothecene biosynthesis and the coordinated expression of four trichothecene pathway-specific genes (Tri4, Tri5, Tri6, and Tri101) and the isoprenoid biosynthetic gene for farnesyl pyrophosphate synthetase (FPPS). We showed that six more trichothecene genes (Tri3, Tri7, Tri8, Tri9, Tri11, and Tri12) are regulated by Tri10. We also constructed a cDNA library from a strain of Fusarium sporotrichioides that overexpresses Tri10 (1Tri10) and used cDNA derived from the 1Tri10 strain and a non-Tri10-expressing strain (⌬Tri10) to differentially screen macroarrays prepared from the cDNA library. This screen identified 15 additional Tri10-regulated transcripts. Four of these transcripts represent Tri1, Tri13, and Tri14 and a gene designated Tri15. Three other sequences are putative orthologs of genes for isoprenoid biosynthesis, the primary metabolic pathway preceding trichothecene biosynthesis. The remaining eight sequences have been designated Ibt (influenced by Tri10) genes. Of the 26 transcripts now known to be positively regulated by Tri10, 22 are positively coregulated by Tri6, a gene that encodes a previously characterized trichothecene pathway-specific transcription factor. These 22 Tri10-and Tri6-coregulated sequences include all of the known Tri genes (except for Tri10), the FPPS gene, and the other three putative isoprenoid biosynthetic genes. Tri6 also regulates a transcript that is not regulated by Tri10. Thus, Tri10 and Tri6 regulate overlapping sets of genes that include a common group of multiple genes for both primary and secondary metabolism.

show abstract

A cis regulatory element in the TAPNAC promoter directs tapetal gene expression

2010

View full text Add to dashboard Cite

The tapetum is a single cell layer surrounding the anther locule and its major function is to provide nutrients for pollen development. The ablation of tapetal cells interferes with pollen production and results in plant male sterility. In spite of the importance of this tissue in the quality and production of pollen grains, studies on promoter gene regulation of tapetal expressed genes are very few and there are no reports on specific cis regulatory sequences that control tapetal gene expression. We have identified a NAC gene, TAPNAC (At1g61110), specifically expressed in the Arabidopsis tapetum via transcriptional profiling. The TAPNAC promoter was studied in detail to identify cis regulatory sequences that confer tapetal specific expression. For this purpose, TAPNAC promoter elements were fused to the β-glucuronidase (GUS) reporter gene, and spatial and temporal GUS expression was monitored. The results showed that TAPNAC promoter-driven GUS expression emulates the expression of TAPNAC mRNA in anthers. A conserved TCGTGT motif was identified in the TAPNAC promoter and other tapetal expressed promoters. The TCGTGT motif enhances GUS expression in anthers of transgenic plants but only in the context of the TAPNAC promoter proximal region.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Andrew G. Tag

Transcription Factors in Light and Circadian Clock Signaling Networks Revealed by Genomewide Mapping of Direct Targets for Neurospora White Collar Complex

A Novel Regulatory Gene, Tri10 , Controls Trichothecene Toxin Production and Gene Expression

G‐protein signalling mediates differential production of toxic secondary metabolites

Identification of New Genes Positively Regulated by Tri10 and a Regulatory Network for Trichothecene Mycotoxin Production

A cis regulatory element in the TAPNAC promoter directs tapetal gene expression

Contact Info

Product

Resources

About