Crystal structure of a Pumilio homology domain

Puf proteins regulate translation and mRNA stability by binding sequences in their target RNAs through the Pumilio homology domain (PUM-HD), which is characterized by eight tandem copies of a 36 amino acid motif, the PUM repeat. We have solved the structure of the PUM-HD from human Pumilio1 at 1.9 A resolution. The structure reveals that the eight PUM repeats correspond to eight copies of a single, repeated structural motif. The PUM repeats pack together to form a right-handed superhelix that approximates a half doughnut. The distribution of side chains on the inner and outer faces of this half doughnut suggests that the inner face of the PUM-HD binds RNA while the outer face interacts with proteins such as Nanos, Brain Tumor, and cytoplasmic polyadenylation element binding protein.     

Cloning and comparative sequence analysis of PUM1 and PUM2 genes,human members of the Pumilio family of RNA-binding proteins

Drosophila gene Pumilio (Pum) is a founder member of an evolutionarily conserved family of RNA-binding proteins that are present from yeast to mammals, and act as translational repressors during embryo development and cell differentiation. The human genome contains two Pumilio related genes, PUM1 and PUM2, that encode 127 and 114 kDa proteins with evolutionarily highly conserved Pum RNA-binding domain (86 and 88% homology with the fly Pum protein). PUM1 and PUM2 proteins share 83% overall similarity, with RNA-binding domain being 91% identical. Both PUM1 and PUM2 show relatively widespread and mostly overlapping expression in human tissues, and are very large genes with highly conserved gene structure. PUM1 consists of 22 exons, spanning about 150 kb on chromosome 1p35.2, whereas PUM2 consists of 20 exons and spans at least 80 kb on chromosome 2p23-24. Extremely high evolutionary conservation of the RNA-binding domain from yeast to humans, and conserved function of Pumilio proteins in invertebrates and lower vertebrates suggest that mammalian Pumilio proteins could also play an important role in translational regulation of embryogenesis and cell development and differentiation.     

The PUF family of RNA-binding proteins: does evolutionarily conserved structure equal conserved function?

Drosophila Pumilio (Pum) protein is a founder member of a novel family of RNA-binding proteins, known as the PUF family. The PUF proteins constitute an evolutionarily highly conserved family of proteins present from yeast to humans and plants, and are characterized by a highly conserved C-terminal RNA-binding domain, composed of eight tandem repeats. The conserved biochemical features and genetic function of PUF family members have emerged from studies of model organisms. PUF proteins bind to related sequence motifs in the 3' untranslated region (3'UTR) of specific target mRNAs and repress their translation. Frequently, PUF proteins function asymmetrically to create protein gradients, thus causing asymmetric cell division and regulating cell fate specification. Thus, it was recently proposed that the primordial role of PUF proteins is to sustain mitotic proliferation of stem cells. Here we review the evolution, conserved genetic and biochemical properties of PUF family of proteins, and discuss protein interactions, upstream regulators and downstream targets of PUF proteins. We also suggest that a conserved mechanism of PUF function extends to the newly described mammalian members of the PUF family (human PUM1 and PUM2, and mouse Pum1 and Pum2), that show extensive homology to Drosophila Pum, and could have an important role in cell development, fate specification and differentiation.     

The malaria parasite Plasmodium falciparum encodes members of the Puf RNA-binding protein family with conserved RNA binding activity

A novel class of RNA-binding proteins, Puf, regulates translation and RNA stability by binding to specific sequences in the 3'-untranslated region of target mRNAs. Members of this protein family share a conserved Puf domain consisting of eight 36 amino acid imperfect repeats. Here we report two Puf family member genes, PfPuf1 and PfPuf2, from the human malaria parasite Plasmodium falciparum. Both genes are spliced with four and three introns clustered within or near the Puf domains, respectively. Northern and RT-PCR analysis indicated that both genes were differentially expressed in gametocytes during erythrocytic development of the parasite. Except for similarities in the Puf domain and expression profile, the deduced PfPuf1 and PfPuf2 proteins differ considerably in size and structure. PfPuf1 has 1894 amino acids and a central Puf domain, whereas PfPuf2 is much smaller with a C-terminal Puf domain. The presence of at least two Puf members in other Plasmodium species suggests that these proteins play evolutionarily similar roles during parasite development. Both in vivo studies using the yeast three-hybrid system and in vitro binding assays using the recombinant Puf domain of PfPuf1 expressed in bacteria demonstrated intrinsic binding activity of the PfPuf1 Puf domain to the NRE sequences in the hunchback RNA, the target sequence for Drosophila Pumilio protein. Altogether, these results suggest that PfPufs might function during sexual differentiation and development in Plasmodium through a conserved mechanism of translational regulation of their target mRNAs.     

A pumilio homolog in Polycelis sp.

Pumilio proteins (PUMs), members of the pumilio/fem-3 mRNA-binding factor (PUF) family, are eukaryote-specific RNA-binding proteins. We isolated a 2,048-basepair cDNA fragment of a pumilio homolog from the planarian flatworm Polycelis sp. This pumilio protein (PyPUM) contains a conserved pumilio homology domain (PUM-HD) consisting of eight repeats and two flanking half repeats. PyPUM shows high similarity to Dugesia japonica pumilio (DjPUM) from another planarian D. japonica, and their PUM-HD also shows high similarity to each other. Furthermore, our data showed that there is a flatworm-specific spacer between repeats 7 and 8. Phylogenetic analysis showed that PyPUM has a closer relationship to other PUM homologs from flatworms. These results provide a foundation for future functional studies of pumilio gene in Polycelis sp.     

A Nucleolar PUF RNA-binding Protein with Specificity for a Unique RNA Sequence

PUF proteins are a conserved group of sequence specific RNA-binding proteins that bind to RNA in a modular fashion. The RNA-binding domain of PUF proteins typically consists of eight clustered Puf repeats. Plant genomes code for large families of PUF proteins that show significant variability in their predicted Puf repeat number, organization, and amino acid sequence. Here we sought to determine whether the observed variability in the RNA-binding domains of four plant PUFs results in a preference for nonclassical PUF RNA target sequences. We report the identification of a novel RNA binding sequence for a nucleolar Arabidopsis PUF protein that contains an atypical RNA-binding domain. The Arabidopsis PUM23 (APUM23) binding sequence was 10 nucleotides in length, contained a centrally located UUGA core element, and had a preferred cytosine at nucleotide position 8. These RNA sequence characteristics differ from those of other PUF proteins, because all natural PUFs studied to date bind to RNAs that contain a conserved UGU sequence at their 5′ end and lack specificity for cytosine. Gel mobility shift assays validated the identity of the APUM23 binding sequence and supported the location of 3 of the 10 predicted Puf repeats in APUM23, including the cytosine-binding repeat. The preferred 10-nucleotide sequence bound by APUM23 is present within the 18S rRNA sequence, supporting the known role of APUM23 in 18S rRNA maturation. This work also reveals that APUM23, an ortholog of yeast Nop9, could provide an advanced structural backbone for Puf repeat engineering and target-specific regulation of cellular RNAs.     

The Pumilio protein binds RNA through a conserved domain that defines a new class of RNA-binding proteins.

Translation of hunchback(mat) (hb[mat]) mRNA must be repressed in the posterior of the pre-blastoderm Drosophila embryo to permit formation of abdominal segments. This translational repression requires two copies of the Nanos Response Element (NRE), a 16-nt sequence in the hb[mat] 3'' untranslated region. Translational repression also requires the action of two proteins: Pumilio (PUM), a sequence-specific RNA-binding protein; and Nanos, a protein that determines the location of repression. Binding of PUM to the NRE is thought to target hb(mat) mRNA for repression. Here, we show the RNA-binding domain of PUM to be an evolutionarily conserved, 334-amino acid region at the carboxy-terminus of the approximately 158-kDa PUM protein. This contiguous region of PUM retains the RNA-binding specificity of full-length PUM protein. Proteins with sequences homologous to the PUM RNA-binding domain are found in animals, plants, and fungi. The high degree of sequence conservation of the PUM RNA-binding domain in other far-flung species suggests that the domain is an ancient protein motif, and we show that conservation of sequence reflects conservation of function: that is, the homologous region from a human protein binds RNA with sequence specificity related to but distinct from Drosophila PUM.     

Structures of human Pumilio with noncognate RNAs reveal molecular mechanisms for binding promiscuity

Pumilio is a founder member of the evolutionarily conserved Puf family of RNA-binding proteins that control a number of physiological processes in eukaryotes. A structure of human Pumilio (hPum) Puf domain bound to a Drosophila regulatory sequence showed that each Puf repeat recognizes a single nucleotide. Puf domains in general bind promiscuously to a large set of degenerate sequences, but the structural basis for this promiscuity has been unclear. Here, we describe the structures of hPum Puf domain complexed to two noncognate RNAs, CycB(reverse) and Puf5. In each complex, one of the nucleotides is ejected from the binding surface, in effect, acting as a "spacer." The complexes also reveal the plasticity of several Puf repeats, which recognize noncanonical nucleotides. Together, these complexes provide a molecular basis for recognition of degenerate binding sites, which significantly increases the number of mRNAs targeted for regulation by Puf proteins in vivo.     

Recruitment of the Puf3 protein to its mRNA target for regulation of mRNA decay in yeast

The Puf family of RNA-binding proteins regulates mRNA translation and decay via interactions with 3' untranslated regions (3' UTRs) of target mRNAs. In yeast, Puf3p binds the 3' UTR of COX17 mRNA and promotes rapid deadenylation and decay. We have investigated the sequences required for Puf3p recruitment to this 3' UTR and have identified two separate binding sites. These sites are specific for Puf3p, as they cannot bind another Puf protein, Puf5p. Both sites use a conserved UGUANAUA sequence, whereas one site contains additional sequences that enhance binding affinity. In vivo, presence of either site partially stimulates COX17 mRNA decay, but full decay regulation requires the presence of both sites. No other sequences outside the 3' UTR are required to mediate this decay regulation. The Puf repeat domain of Puf3p is sufficient not only for in vitro binding to the 3' UTR, but also in vivo stimulation of COX17 mRNA decay. These experiments indicate that the essential residues involved in mRNA decay regulation are wholly contained within this RNA-binding domain.     

Drosophila Pumilio protein contains multiple autonomous repression domains that regulate mRNAs independently of Nanos and brain tumor

Drosophila melanogaster Pumilio is an RNA-binding protein that potently represses specific mRNAs. In developing embryos, Pumilio regulates a key morphogen, Hunchback, in collaboration with the cofactor Nanos. To investigate repression by Pumilio and Nanos, we created cell-based assays and found that Pumilio inhibits translation and enhances mRNA decay independent of Nanos. Nanos robustly stimulates repression through interactions with the Pumilio RNA-binding domain. We programmed Pumilio to recognize a new binding site, which garners repression of new target mRNAs. We show that cofactors Brain Tumor and eIF4E Homologous Protein are not obligatory for Pumilio and Nanos activity. The conserved RNA-binding domain of Pumilio was thought to be sufficient for its function. Instead, we demonstrate that three unique domains in the N terminus of Pumilio possess the major repressive activity and can function autonomously. The N termini of insect and vertebrate Pumilio and Fem-3 binding factors (PUFs) are related, and we show that corresponding regions of human PUM1 and PUM2 have repressive activity. Other PUF proteins lack these repression domains. Our findings suggest that PUF proteins have evolved new regulatory functions through protein sequences appended to their conserved PUF repeat RNA-binding domains.     

Interaction of the conserved meiotic regulators, BOULE (BOL) and PUMILIO-2 (PUM2)

Germ cell development is complex; it encompasses specification of germ cell fate, mitotic replication of early germ cell populations, and meiotic and postmeiotic development. Meiosis alone may require several hundred genes, including homologs of the BOULE (BOL) and PUMILIO (PUM) gene families. Both BOL and PUM homologs encode germ cell specific RNA binding proteins in diverse organisms where they are required for germ cell development. Here, we demonstrate that human BOL forms homodimers and is able to interact with a PUMILIO homolog, PUM2. We mapped the domain of BOL that is required for dimerization and for interaction with PUM2. We also show that BOL and PUM2 can form a complex on a subset of PUM2 RNA targets that is distinct from targets bound by PUM2 and another deleted in azoospermia (DAZ) family member, DAZ-like (DAZL). This suggests that RNA sequences bound by PUM2 may be determined by protein interactions. This data also suggests that although the BOL, DAZ, and DAZL proteins are all members of the same gene family, they may function in distinct molecular complexes during human germ cell development.