Poly(ADP-Ribose) Polymerase 1 (PARP-1) Regulates Ribosomal Biogenesis in Drosophila Nucleoli

Poly(ADP-ribose) polymerase 1 (PARP1), a nuclear protein, utilizes NAD to synthesize poly(AD-Pribose) (pADPr), resulting in both automodification and the modification of acceptor proteins. Substantial amounts of PARP1 and pADPr (up to 50%) are localized to the nucleolus, a subnuclear organelle known as a region for ribosome biogenesis and maturation. At present, the functional significance of PARP1 protein inside the nucleolus remains unclear. Using PARP1 mutants, we investigated the function of PARP1, pADPr, and PARP1-interacting proteins in the maintenance of nucleolus structure and functions. Our analysis shows that disruption of PARP1 enzymatic activity caused nucleolar disintegration and aberrant localization of nucleolar-specific proteins. Additionally, PARP1 mutants have increased accumulation of rRNA intermediates and a decrease in ribosome levels. Together, our data suggests that PARP1 enzymatic activity is required for targeting nucleolar proteins to the proximity of precursor rRNA; hence, PARP1 controls precursor rRNA processing, post-transcriptional modification, and pre-ribosome assembly. Based on these findings, we propose a model that explains how PARP1 activity impacts nucleolar functions and, consequently, ribosomal biogenesis

RNA processing of beta-globin transcripts containing 5' flanking and structural gene sequences.

RNA species have been identified in murine erythroid cells which contain both 5' flanking and structural gene sequences from the beta maj globin gene. Two nonpolyadenylated RNA transcripts, average 3700 and 1800-1900 nucleotides long, were identified by denaturing agarose gel electrophoresis and were found to hybridize to both 5' and 3' beta maj globin flanking sequences. This finding suggests that transcription initiated in the 5' flanking region does proceed past the polyadenylation site. The apparent higher concentration of the 5' flanking sequences in precursor RNA molecules, as compared to mature polyadenylated globin mRNA, suggests increased precursor stability of beta globin transcripts initiated in the 5' flanking region

Two 10-bp regions are critical for phytochrome regulation of a Lemna gibba Lhcb gene promoter.

Two small regions of the promoter of an Lhcb gene encoding a light-harvesting chlorophyll a/b protein were identified as essential in conferring phytochrome responsiveness by using a transient expression assay. Initially, 5' deletion analysis of cabAB19, an Lhcb2 gene of Lemna, showed that sequences within the region from -174 to -104 relative to the start of transcription were necessary for phytochrome regulation. Internal deletion and substitution mutants were used to demonstrate that no additional phytochrome-responsive regions exist between -1600 and -174 in this promoter. A 171-bp fragment of the promoter extending from -239 to -69 was sufficient to impart phytochrome responsiveness to a minimal ubiquitin promoter that was not itself regulated by light. Specific binding of Lemna proteins to the region necessary for phytochrome responsiveness was demonstrated using in vitro polyacrylamide gel mobility shift assays and 1,10-phenanthroline copper ion footprinting. Further analysis of the region from -174 to -104 demonstrated that mutations in two separate 10-bp sequences, from -134 to -125 and from -114 to -105, could abolish phytochrome responsiveness; thus, there are two unique regions that are necessary for phytochrome regulation of this gene. One of these regions contains a CCAAT motif and the other a GATA motif. These motifs are conserved in the promoters of many Lhcb genes and may be important elements in the phytochrome responsiveness of this gene family