Anusha P. Dias
Harvard University
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Featured researches published by Anusha P. Dias.
Proceedings of the National Academy of Sciences of the United States of America | 2008
Patricia Valencia; Anusha P. Dias; Robin Reed
The numerous steps in protein gene expression are extensively coupled to one another through complex networks of physical and functional interactions. Indeed, >25 coupled reactions, often reciprocal, have been documented among such steps as transcription, capping, splicing, and polyadenylation. Coupling is usually not essential for gene expression, but instead enhances the rate and/or efficiency of reactions and, physiologically, may serve to increase the fidelity of gene expression. Despite numerous examples of coupling in gene expression, whether splicing enhances mRNA export still remains controversial. Although splicing was originally reported to promote export in both mammalian cells and Xenopus oocytes, it was subsequently concluded that this was not the case. These newer conclusions were surprising in light of the observations that the mRNA export machinery colocalizes with splicing factors in the nucleus and that splicing promotes recruitment of the export machinery to mRNA. We therefore reexamined the relationship between splicing and mRNA export in mammalian cells by using FISH, in combination with either transfection or nuclear microinjection of plasmid DNA. Together, these analyses indicate that both the kinetics and efficiency of mRNA export are enhanced 6- to 10-fold (depending on the construct) for spliced mRNAs relative to their cDNA counterparts. We conclude that splicing promotes mRNA export in mammalian cells and that the functional coupling between splicing and mRNA export is a conserved and general feature of gene expression in higher eukaryotes.
Plant Physiology | 2003
Anusha P. Dias; Edward L. Braun; Michael D. McMullen; Erich Grotewold
R2R3 Myb genes are widely distributed in the higher plants and comprise one of the largest known families of regulatory proteins. Here, we provide an evolutionary framework that helps explain the origin of the plant-specific R2R3 Myb genes from widely distributed R1R2R3 Mybgenes, through a series of well-established steps. To understand the routes of sequence divergence that followed Myb gene duplication, we supplemented the information available on recently duplicated maize (Zea mays) R2R3 Mybgenes (C1/Pl1 andP1/P2) by cloning and characterizingZmMyb-IF35 and ZmMyb-IF25. These two genes correspond to the recently expanded P-to-A group of maizeR2R3 Myb genes. Although the origins ofC1/Pl1 andZmMyb-IF35/ZmMyb-IF25 are associated with the segmental allotetraploid origin of the maize genome, other gene duplication events also shaped the P-to-A clade. Our analyses indicate that some recently duplicated Myb gene pairs display substantial differences in the numbers of synonymous substitutions that have accumulated in the conserved MYB domain and the divergent C-terminal regions. Thus, differences in the accumulation of substitutions during evolution can explain in part the rapid divergence of C-terminal regions for these proteins in some cases. Contrary to previous studies, we show that the divergent C termini of these R2R3 MYB proteins are subject to purifying selection. Our results provide an in-depth analysis of the sequence divergence for some recently duplicated R2R3 Myb genes, yielding important information on general patterns of evolution for this large family of plant regulatory genes.
Nucleic Acids Research | 2008
Chung-Sheng Lee; Anusha P. Dias; Mark P. Jedrychowski; Arvind H. Patel; Jeanne L. Hsu; Robin Reed
The conserved RNA helicase DDX3 is of major medical importance due to its involvement in numerous cancers, human hepatitis C virus (HCV) and HIV. Although DDX3 has been reported to have a wide variety of cellular functions, its precise role remains obscure. Here, we raised a new antibody to DDX3 and used it to show that DDX3 is evenly distributed throughout the cytoplasm at steady state. Consistent with this observation, HA-tagged DDX3 also localizes to the cytoplasm. RNAi of DDX3 in both human and Drosophila cells shows that DDX3 is required for cell viability. Moreover, using RNAi, we show that DDX3 is required for expression of protein from reporter constructs. In contrast, we did not detect a role for DDX3 in nuclear steps in gene expression. Further insight into the function of DDX3 came from the observation that its major interaction partner is the multi-component translation initiation factor eIF3. We conclude that a primary function for DDX3 is in protein translation, via an interaction with eIF3.
Nature Communications | 2010
Anusha P. Dias; Kobina Dufu; Haixin Lei; Robin Reed
The TREX complex, which functions in mRNA export, is recruited to mRNA during splicing. Both the splicing machinery and the TREX complex are concentrated in 20-50 discrete foci known as nuclear speckle domains. In this study, we use a model system where DNA constructs are microinjected into HeLa cell nuclei, to follow the fates of the transcripts. We show that transcripts lacking functional splice sites, which are inefficiently exported, do not associate with nuclear speckle domains but are instead distributed throughout the nucleoplasm. In contrast, pre-mRNAs containing functional splice sites accumulate in nuclear speckles, and our data suggest that splicing occurs in these domains. When the TREX components UAP56 or Aly are knocked down, spliced mRNA, as well as total polyA+ RNA, accumulates in nuclear speckle domains. Together, our data raise the possibility that pre-mRNA undergoes splicing in nuclear speckle domains, before their release by TREX components for efficient export to the cytoplasm.
PLOS Biology | 2007
Alexander F. Palazzo; Michael Springer; Yoko Shibata; Chung-Sheng Lee; Anusha P. Dias
In eukaryotic cells, most mRNAs are exported from the nucleus by the transcription export (TREX) complex, which is loaded onto mRNAs after their splicing and capping. We have studied in mammalian cells the nuclear export of mRNAs that code for secretory proteins, which are targeted to the endoplasmic reticulum membrane by hydrophobic signal sequences. The mRNAs were injected into the nucleus or synthesized from injected or transfected DNA, and their export was followed by fluorescent in situ hybridization. We made the surprising observation that the signal sequence coding region (SSCR) can serve as a nuclear export signal of an mRNA that lacks an intron or functional cap. Even the export of an intron-containing natural mRNA was enhanced by its SSCR. Like conventional export, the SSCR-dependent pathway required the factor TAP, but depletion of the TREX components had only moderate effects. The SSCR export signal appears to be characterized in vertebrates by a low content of adenines, as demonstrated by genome-wide sequence analysis and by the inhibitory effect of silent adenine mutations in SSCRs. The discovery of an SSCR-mediated pathway explains the previously noted amino acid bias in signal sequences and suggests a link between nuclear export and membrane targeting of mRNAs.
Proceedings of the National Academy of Sciences of the United States of America | 2011
Haixin Lei; Anusha P. Dias; Robin Reed
A great deal is known about the export of spliced mRNAs, but little is known about the export of mRNAs encoded by human cellular genes that naturally lack introns. Here, we investigated the requirements for export of three naturally intronless mRNAs (HSPB3, IFN-α1, and IFN-β1). Significantly, we found that all three mRNAs are stable and accumulate in the cytoplasm, whereas size-matched random RNAs are unstable and detected only in the nucleus. A portion of the coding region confers this stability and cytoplasmic localization on the naturally intronless mRNAs and a cDNA transcript, which is normally retained in the nucleus and degraded. A polyadenylation signal, TREX mRNA export components, and the mRNA export receptor TAP are required for accumulation of the naturally intronless mRNAs in the cytoplasm. We conclude that naturally intronless mRNAs contain specific sequences that result in efficient packaging into the TREX mRNA export complex, thereby supplanting the splicing requirement for efficient mRNA export.
Biochemical Engineering Journal | 2003
Anusha P. Dias; Erich Grotewold
Transcription factors are emerging as powerful tools to manipulating plant metabolism. R2R3 Myb genes have expanded dramatically in the plants, where they are involved in the regulation of plant form and metabolic diversity. However, the function of most plant R2R3 Myb genes remains to be determined. We have used a maize cell culture system to investigate the consequences on the accumulation of metabolites of expressing the novel R2R3 Myb transcription factor ZmMyb-IF35. We show here that, despite the high identity in the Myb domain with the P regulator of 3-deoxy flavonoid biosynthesis, ZmMyb-IF35 does not induce the accumulation of flavonoids. However, similar to P, ZmMyb-IF35 induces the accumulation of ferulic and chlorogenic acids as well as several other compounds not found in the control Black Mexican Sweet maize cell lines or in P-expressing lines. Together, our studies show that ZmMyb-IF35 and P activate different biosynthetic pathways, and suggest a promising role of ZmMyb-IF35 for engineering the accumulation of various phenolic compounds.
Recent Advances in Phytochemistry | 2001
Edward L. Braun; Anusha P. Dias; Todd Matulnik; Erich Grotewold
Publisher Summary The plant kingdom provides a vast source of compounds with important biological activities, and ambitious projects to exploit this diversity have been undertaken. The time when plants and cultured plant cells will be routinely used as factories to produce compounds with importance to medicine and agriculture has yet to come, but important progress in the area of plant metabolic engineering has been made. Transcription factors are emerging as important tools for these processes because they allow the activation of entire pathways with just one or a small number of transgenes. One of the main challenges in the future will be establishing the regulation of important plant metabolic pathways. The regulation of phytochemical accumulation by transcription factors is complex, with distinct types of transcription factors contributing to the regulation of various enzymes involved in both primary and secondary metabolism.
Cell discovery | 2015
Min Shi; Heng Zhang; Lantian Wang; Changlan Zhu; Ke Sheng; Yanhua Du; Ke Wang; Anusha P. Dias; She Chen; Malcolm Whitman; Enduo Wang; Robin Reed; Hong Cheng
mRNAs containing premature termination codons (PTCs) are known to be degraded via nonsense-mediated mRNA decay (NMD). Unexpectedly, we found that mRNAs containing any type of PTCs (UAA, UAG, and UGA) are detained in the nucleus, whereas their wild-type counterparts are rapidly exported. This retention is strictly reading-frame dependent. Strikingly, our data indicate that translating ribosomes in the nucleus proofread the frame and detect the PTCs in the nucleus. Moreover, the shuttling NMD protein Upf1 specifically associates with PTC+mRNAs (PTC-containing mRNAs) in the nucleus and is required for nuclear retention of PTC+mRNAs. Together, our data lead to a working model that PTCs are recognized in the nucleus by translating ribosomes, resulting in recruitment of Upf1, which in turn functions in nuclear retention of PTC+mRNA. Nuclear PTC recognition adds a new layer of proofreading for mRNA and may be vital for ensuring the extraordinary fidelity required for protein production.
Methods of Molecular Biology | 2003
Anusha P. Dias; Johnny Brown; Pierluigi Bonello; Erich Grotewold
Plants accumulate a very large number of small molecules (phytochemicals) with important functions in the ecology of plants and in the protection against biotic and abiotic stress conditions. Little is known on how phytochemical biosynthetic pathways are regulated, which is a key step to successfully engineering plant metabolism. Plant natural products are usually not essential, and genetic analyses often fail to identify phenotypes associated with the absence of these compounds. We have investigated the use of metabolite profiling of plant cells in culture to establish the function of transcription factors suspected to control plant metabolic pathways.