Victoria Brown

Microarray identification of FMRP-associated brain mRNAs and altered mRNA translational profiles in fragile X syndrome.

Fragile X syndrome results from the absence of the RNA binding FMR protein. Here, mRNA was coimmunoprecipitated with the FMRP ribonucleoprotein complex and used to interrogate microarrays. We identified 432 associated mRNAs from mouse brain. Quantitative RT-PCR confirmed some to be >60-fold enriched in the immunoprecipitant. In parallel studies, mRNAs from polyribosomes of fragile X cells were used to probe microarrays. Despite equivalent cytoplasmic abundance, 251 mRNAs had an abnormal polyribosome profile in the absence of FMRP. Although this represents <2% of the total messages, 50% of the coimmunoprecipitated mRNAs with expressed human orthologs were found in this group. Nearly 70% of those transcripts found in both studies contain a G quartet structure, demonstrated as an in vitro FMRP target. We conclude that translational dysregulation of mRNAs normally associated with FMRP may be the proximal cause of fragile X syndrome, and we identify candidate genes relevant to this phenotype.

Fragile X Mental Retardation Protein Targets G Quartet mRNAs Important for Neuronal Function

Loss of fragile X mental retardation protein (FMRP) function causes the fragile X mental retardation syndrome. FMRP harbors three RNA binding domains, associates with polysomes, and is thought to regulate mRNA translation and/or localization, but the RNAs to which it binds are unknown. We have used RNA selection to demonstrate that the FMRP RGG box binds intramolecular G quartets. This data allowed us to identify mRNAs encoding proteins involved in synaptic or developmental neurobiology that harbor FMRP binding elements. The majority of these mRNAs have an altered polysome association in fragile X patient cells. These data demonstrate that G quartets serve as physiologically relevant targets for FMRP and identify mRNAs whose dysregulation may underlie human mental retardation.

FMRP Associates with Polyribosomes as an mRNP, and the I304N Mutation of Severe Fragile X Syndrome Abolishes This Association

Fragile X mental retardation is caused by the lack of FMRP, a selective RNA-binding protein associated with ribosomes. A missense mutation, I304N, has been found to result in an unusually severe phenotype. We show here that normal FMRP associates with elongating polyribosomes via large mRNP particles. Despite normal expression and cytoplasmic mRNA association, the I304N FMRP is incorporated into abnormal mRNP particles that are not associated with polyribosomes. These data indicate that association of FMRP with polyribosomes must be functionally important and imply that the mechanism of the severe phenotype in the I304N patient lies in the sequestration of bound mRNAs in nontranslatable mRNP particles. In the absence of FMRP, these same mRNAs may be partially translated via alternative mRNPs, although perhaps abnormally localized or regulated, resulting in typical fragile X syndrome.

Targeted Genome Modification in Mice Using Zinc Finger Nucleases

Homologous recombination-based gene targeting using Mus musculus embryonic stem cells has greatly impacted biomedical research. This study presents a powerful new technology for more efficient and less time-consuming gene targeting in mice using embryonic injection of zinc-finger nucleases (ZFNs), which generate site-specific double strand breaks, leading to insertions or deletions via DNA repair by the nonhomologous end joining pathway. Three individual genes, multidrug resistant 1a (Mdr1a), jagged 1 (Jag1), and notch homolog 3 (Notch3), were targeted in FVB/N and C57BL/6 mice. Injection of ZFNs resulted in a range of specific gene deletions, from several nucleotides to >1000 bp in length, among 20–75% of live births. Modified alleles were efficiently transmitted through the germline, and animals homozygous for targeted modifications were obtained in as little as 4 months. In addition, the technology can be adapted to any genetic background, eliminating the need for generations of backcrossing to achieve congenic animals. We also validated the functional disruption of Mdr1a and demonstrated that the ZFN-mediated modifications lead to true knockouts. We conclude that ZFN technology is an efficient and convenient alternative to conventional gene targeting and will greatly facilitate the rapid creation of mouse models and functional genomics research.

Isolation of an FMRP-Associated Messenger Ribonucleoprotein Particle and Identification of Nucleolin and the Fragile X-Related Proteins as Components of the Complex

ABSTRACT The loss of FMR1 expression due to trinucleotide repeat expansion leads to fragile X syndrome, a cause of mental retardation. The encoded protein, FMRP, is a member of a gene family that also contains the fragile X-related proteins, FXR1P and FXR2P. FMRP has been shown to be a nucleocytoplasmic shuttling protein that selectively binds a subset of mRNAs, forms messenger ribonucleoprotein (mRNP) complexes, and associates with translating ribosomes. Here we describe a cell culture system from which we can isolate epitope-tagged FMRP along with mRNA, including its own message, and at least six other proteins. We identify two of these proteins as FXR1P and FXR2P by using specific antisera and identify a third protein as nucleolin by using mass spectrometry. The presence of nucleolin is confirmed by both reactivity with a specific antiserum as well as reverse coimmunoprecipitation where antinucleolin antiserum immunoprecipitates endogenous FMRP from both cultured cells and mouse brain. The identification of nucleolin, a known component of other mRNPs, adds a new dimension to the analysis of FMRP function, and the approach described should also allow the identification of the remaining unknown proteins of this FMRP-associated mRNP as well as the other bound mRNAs.

A Glucose Sensor in Candida albicans

ABSTRACT The Hgt4 protein of Candida albicans (orf19.5962) is orthologous to the Snf3 and Rgt2 glucose sensors of Saccharomyces cerevisiae that govern sugar acquisition by regulating the expression of genes encoding hexose transporters. We found that HGT4 is required for glucose induction of the expression of HGT12, HXT10, and HGT7, which encode apparent hexose transporters in C. albicans. An hgt4Δ mutant is defective for growth on fermentable sugars, which is consistent with the idea that Hgt4 is a sensor of glucose and similar sugars. Hgt4 appears to be sensitive to glucose levels similar to those in human serum (∼5 mM). HGT4 expression is repressed by high levels of glucose, which is consistent with the idea that it encodes a high-affinity sugar sensor. Glucose sensing through Hgt4 affects the yeast-to-hyphal morphological switch of C. albicans cells: hgt4Δ mutants are hypofilamented, and a constitutively signaling form of Hgt4 confers hyperfilamentation of cells. The hgt4Δ mutant is less virulent than wild-type cells in a mouse model of disseminated candidiasis. These results suggest that Hgt4 is a high-affinity glucose sensor that contributes to the virulence of C. albicans.

Glucose Sensing Network in Candida albicans: a Sweet Spot for Fungal Morphogenesis

Glucose, a ubiquitous carbon source preferred by most cells ([96][1]), was first identified by Andreas Marggraf in 1747 ([67][2]). Even though it is the most abundant hexose on earth ([33][3]), glucose is often a limiting nutrient in biological systems ([2][4]); it is a precious resource for which

Regulation of sugar transport and metabolism by the Candida albicans Rgt1 transcriptional repressor

The ability of the fungal pathogen Candida albicans to cause systemic infections depends in part on the function of Hgt4, a cell surface sugar sensor. The orthologues of Hgt4 in Saccharomyces cerevisiae, Snf3 and Rgt2, initiate a signalling cascade that inactivates Rgt1, a transcriptional repressor of genes encoding hexose transporters. To determine whether Hgt4 functions similarly through the C. albicans orthologue of Rgt1, we analysed Cargt1 deletion mutants. We found that Cargt1 mutants are sensitive to the glucose analogue 2‐deoxyglucose, a phenotype probably due to uncontrolled expression of genes encoding glucose transporters. Indeed, transcriptional profiling revealed that expression of about two dozen genes, including multiple HGT genes encoding hexose transporters, is increased in the Cargt1 mutant in the absence of sugars, suggesting that CaRgt1 represses expression of several HGT genes under this condition. Some of the HGT genes (probably encoding high‐affinity transporters) are also repressed by high levels of glucose, and we show that this repression is mediated by CaMig1, the orthologue of the major glucose‐activated repressor in S. cerevisiae, but not by its paralogue CaMig2. Therefore, CaRgt1 and CaMig1 collaborate to control expression of C. albicans hexose transporters in response to different levels of sugars. We were surprised to find that CaRgt1 also regulates expression of GAL1, suggesting that regulation of galactose metabolism in C. albicans is unconventional. Finally, Cargt1 mutations cause cells to hyperfilament, and suppress the hypofilamented phenotype of an hgt4 mutant, indicating that the Hgt4 glucose sensor may affect filamentation by modulating sugar import and metabolism via CaRgt1. Copyright