Alexandra Moreira scite author profile

We show that mutation in polo leads to a variety of abnormal mitoses in Drosophila larval neuroblasts. These include otherwise normal looking mitotic spindles upon which chromosomes appear overcondensed; normal bipolar spindles with polyploid complements of chromosomes; bipolar spindles in which one pole can be unusually broad; and monopolar spindles. We have cloned the polo gene from a mutant allele carrying a P-element transposon and sequenced cDNAs corresponding to transcripts of the wild-type locus. The sequence shows that polo encodes a 577-amino-acid protein with an amino-terminal domain homologous to a serine-threonine protein kinase, polo transcripts are abundant in tissues and developmental stages in which there is extensive mitotic activity. The transcripts show no obvious spatial pattern of distribution in relation to the mitotic domains of cellularized embryos but are specifically concentrated in dividing cells in larval discs and brains. In the cell cycles of both syncytial and cellularized embryos, the polo kinase undergoes cell cycle-dependent changes in its distribution: It is predominantly cytoplasmic during interphase; it becomes associated with condensed chromosomes toward the end of prophase; and it remains associated with chromosomes until telophase, whereupon it becomes cytoplasmic.

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The upstream sequence element of the C2 complement poly(A) signal activates mRNA 3′ end formation by two distinct mechanisms

Moreira

Takagaki²,

et al. 1998

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The poly(A) signal of the C2 complement gene is unusual in that it possesses an upstream sequence element (USE) required for full activity in vivo. We describe here in vitro experiments demonstrating that this USE enhances both the cleavage and poly(A) addition reactions. We also show that the C2 USE can be cross-linked efficiently to a 55-kD protein that we identify as the polypyrimidine tract-binding protein (PTB), implicated previously in modulation of pre-mRNA splicing. Mutation of the PTB-binding site significantly reduces the efficiency of the C2 poly(A) site both in vivo and in vitro. Furthermore, addition of PTB to reconstituted processing reactions enhances cleavage at the C2 poly(A) site, indicating that PTB has a direct role in recognition of this signal. The C2 USE, however, also increases the affinity of general polyadenylation factors independently for the C2 poly(A) signal as detected by enhanced binding of cleavage-stimulaton factor (CstF). Strikingly, this leads to a novel CstF-dependant enhancement of the poly(A) synthesis phase of the reaction. These studies both emphasize the interconnection between splicing and polyadenylation and indicate an unexpected flexibility in the organization of mammalian poly(A) sites.

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RNA polymerase II kinetics inpolopolyadenylation signal selection

et al. 2011

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Regulated alternative polyadenylation is an important feature of gene expression, but how gene transcription rate affects this process remains to be investigated. polo is a cell-cycle gene that uses two poly(A) signals in the 3 0 untranslated region (UTR) to produce alternative messenger RNAs that differ in their 3 0 UTR length. Using a mutant Drosophila strain that has a lower transcriptional elongation rate, we show that transcription kinetics can determine alternative poly(A) site selection. The physiological consequences of incorrect polo poly(A) site choice are of vital importance; transgenic flies lacking the distal poly(A) signal cannot produce the longer transcript and die at the pupa stage due to a failure in the proliferation of the precursor cells of the abdomen, the histoblasts. This is due to the low translation efficiency of the shorter transcript produced by proximal poly(A) site usage. Our results show that correct polo poly(A) site selection functions to provide the correct levels of protein expression necessary for histoblast proliferation, and that the kinetics of RNA polymerase II have an important role in the mechanism of alternative polyadenylation.

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Polypyrimidine Tract Binding Protein Modulates Efficiency of Polyadenylation

Castelo‐Branco

Furger

Wollerton

et al. 2004

Molecular and Cellular Biology

160

145

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Polypyrimidine tract binding protein (PTB) is a major hnRNP protein with multiple roles in mRNA metabolism, including regulation of alternative splicing and internal ribosome entry site-driven translation. We show here that a fourfold overexpression of PTB results in a 75% reduction of mRNA levels produced from transfected gene constructs with different polyadenylation signals (pA signals). This effect is due to the reduced efficiency of mRNA 3 end cleavage, and in vitro analysis reveals that PTB competes with CstF for recognition of the pA signal's pyrimidine-rich downstream sequence element. This may be analogous to its role in alternative splicing, where PTB competes with U2AF for binding to pyrimidine-rich intronic sequences. The pA signal of the C2 complement gene unusually possesses a PTB-dependent upstream sequence, so that knockdown of PTB expression by RNA interference reduces C2 mRNA expression even though PTB overexpression still inhibits polyadenylation. Consequently, we show that PTB can act as a regulator of mRNA expression through both its negative and positive effects on mRNA 3 end processing.Between the branch point and the 3Ј splice site (3ЈSS) of metazoan introns lies a pyrimidine-rich sequence which is critical for efficient splicing (49). Initial analysis of factors that recognize this sequence identified an hnRNP-like protein called polypyrimidine tract binding protein (PTB) or hnRNP I (20,22,23,40). PTB has strong RNA binding activity, since it possesses four tandem RNA recognition motif domains (42). In vitro RNA binding analysis (SELEX) revealed its preferred RNA binding site as UCUU flanked by pyrimidines rather than a nonspecific pyrimidine sequence (41). Subsequent studies indicated that far from being a positively acting splicing factor, PTB actually acts as a selective splicing repressor (55, 57). The splicing factor responsible for recognition of the 3ЈSS pyrimidine tract and AG dinucleotide is the dimeric U2 auxiliary factor protein or U2AF (7). The U2AF 65-kDa subunit interacts with the pyrimidine tract (63), while the smaller 35-kDa subunit directly contacts the 3ЈSS sequence (34). Recognition of the pyrimidine tract by U2AF has been identified as a major site of splicing regulation. This can be modulated in a positive fashion through interaction with splicing-regulatory proteins bound to adjacent exon enhancer sequences (4, 51) or in a negative fashion by competition for binding with PTB (57). In many cases the pyrimidine tract of PTB-regulated exons contains high-affinity binding sites for PTB (41), and direct competition between PTB and U2AF 65 for binding to the pyrimidine tract can lead to exon skipping (28, 50). However, regulation by PTB often requires additional PTB-binding elements remote from the 3ЈSS pyrimidine tract. These may mediate cooperative binding of PTB (11), which can interfere with binding of U2AF as well as other splicing factors (57). Furthermore, PTB exists in several different isoforms generated by alternative splicing (PTB1-referred to throughout the p...

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Alternative mRNA polyadenylation in eukaryotes: an effective regulator of gene expression

2010

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Alternative RNA processing mechanisms, including alternative splicing and alternative polyadenylation, are increasingly recognized as important regulators of gene expression. This article will focus on what has recently been described about alternative polyadenylation in development, differentiation, and disease in higher eukaryotes. We will also describe how the evolving global methodologies for examining the cellular transcriptome, both experimental and bioinformatic, are revealing new details about the complex nature of alternative 3′ end formation, as well as interactions with other RNA-mediated and RNA processing mechanisms.

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