A novel karyoskeletal protein: characterization of protein NO145, the major component of nucleolar cortical skeleton in Xenopus oocytes

Liquid phase condensation in cell physiology and disease

Phase transitions are ubiquitous in nonliving matter, and recent discoveries have shown that they also play a key role within living cells. Intracellular liquid-liquid phase separation is thought to drive the formation of condensed liquid-like droplets of protein, RNA, and other biomolecules, which form in the absence of a delimiting membrane. Recent studies have elucidated many aspects of the molecular interactions underlying the formation of these remarkable and ubiquitous droplets and the way in which such interactions dictate their material properties, composition, and phase behavior. Here, we review these exciting developments and highlight key remaining challenges, particularly the ability of liquid condensates to both facilitate and respond to biological function and how their metastability may underlie devastating protein aggregation diseases.

Evolutionary history of the mammalian synaptonemal complex

The synaptonemal complex (SC), a key structure of meiosis that assembles during prophase I, has been initially described 60 years ago. Since then, the structure has been described in many sexually reproducing organisms. However, the SC protein components were characterized in only few model organisms. Surprisingly, they lacked an apparent evolutionary relationship despite the conserved structural organization of the SC. For better understanding of this obvious discrepancy, the evolutionary history of the SC and its individual components has been investigated in Metazoa in detail. The results are consistent with the notion of a single origin of the metazoan SC and provide evidence for a dynamic evolutionary history of the SC components. In this mini review, we recapitulate and discuss new insights into metazoan SC evolution.

Active liquid-like behavior of nucleoli determines their size and shape in Xenopus laevis oocytes

For most intracellular structures with larger than molecular dimensions, little is known about the connection between underlying molecular activities and higher order organization such as size and shape. Here, we show that both the size and shape of the amphibian oocyte nucleolus ultimately arise because nucleoli behave as liquid-like droplets of RNA and protein, exhibiting characteristic viscous fluid dynamics even on timescales of < 1 min. We use these dynamics to determine an apparent nucleolar viscosity, and we show that this viscosity is ATP-dependent, suggesting a role for active processes in fluidizing internal contents. Nucleolar surface tension and fluidity cause their restructuring into spherical droplets upon imposed mechanical deformations. Nucleoli exhibit a broad distribution of sizes with a characteristic power law, which we show is a consequence of spontaneous coalescence events. These results have implications for the function of nucleoli in ribosome subunit processing and provide a physical link between activity within a macromolecular assembly and its physical properties on larger length scales.

Regulatory mechanisms governing the oocyte-specific synthesis of the karyoskeletal protein NO145

Given the prominence and the biological importance of the nucleus it is remarkable how little is still known about structure-forming proteins in the nuclear interior. The karyoskeletal protein NO145 has been identified as a major constituent of a filamentous network surrounding the amplified nucleoli of Xenopus laevis oocytes. We now show that an orthologous protein also occurs in female germ cells of a wide range of other vertebrates, where it forms dot-like structures. Using the Xenopus oocyte system we further report a specific regulatory mechanism responsible for (1) the rapid degradation of the NO145 protein during meiotic maturation, and (2) the cell-type-dependent translation of NO145 mRNA. Microinjection experiments have revealed that NO145 is a target of proteasomes and the use of the rapid amplification of cDNA ends-polyadenylation test (RACE-PAT) has disclosed the existence of NO145 mRNAs differing in their 3' UTRs. Reporter systems as well as polyribosome profiling experiments have revealed the regulatory importance of the 3' UTRs, which affect the translational efficiency as well as the stability of the encoded protein. The highly conserved cell-type specificity and the extremely tight temporal regulation of NO145 synthesis suggest an important role of this protein in female meiotic prophase.

Signal recognition particle assembly in relation to the function of amplified nucleoli ofXenopusoocytes

The signal recognition particle (SRP) is a ribonucleoprotein machine that controls the translation and intracellular sorting of membrane and secreted proteins. The SRP contains a core RNA subunit with which six proteins are assembled. Recent work in both yeast and mammalian cells has identified the nucleolus as a possible initial site of SRP assembly. In the present study, SRP RNA and protein components were identified in the extrachromosomal, amplified nucleoli of Xenopus laevis oocytes. Fluorescent SRP RNA microinjected into the oocyte nucleus became specifically localized in the nucleoli, and endogenous SRP RNA was also detected in oocyte nucleoli by RNA in situ hybridization. An initial step in the assembly of SRP involves the binding of the SRP19 protein to SRP RNA. When green fluorescent protein (GFP)-tagged SRP19 protein was injected into the oocyte cytoplasm it was imported into the nucleus and became concentrated in the amplified nucleoli. After visiting the amplified nucleoli, GFP-tagged SRP19 protein was detected in the cytoplasm in a ribonucleoprotein complex, having a sedimentation coefficient characteristic of the SRP. These results suggest that the amplified nucleoli of Xenopus oocytes produce maternal stores not only of ribosomes, the classical product of nucleoli, but also of SRP, presumably as a global developmental strategy for stockpiling translational machinery for early embryogenesis.

Protein NO52—a constitutive nucleolar component sharing high sequence homologies to protein NO66

The nucleolus is the most prominent intranuclear structure of almost all protein-synthesizing cells. It compromises a well-defined functional compartmentalization and a high complexity of molecular constituents. Here, we report on the identification and molecular characterization of a novel constitutive nucleolar component--protein NO52--that is present in diverse species from Xenopus laevis to human. The cDNA-deduced amino acid sequence of protein NO52 defines a polypeptide of a calculated mass of 52.8 kDa and an isoelectric point of 6.7. Inspection of the primary sequence disclosed that the protein contains a JmjC domain and is highly sequence-related to the recently described nucleolar protein NO66. Immunolocalization studies revealed that protein NO52 is highly concentrated in the granular component of nucleoli and this characteristic intranuclear distribution is significantly affected by treatment of cells with (i) RNase A, (ii) actinomycin D and (iii) serum starvation. Interestingly, protein NO52 has been identified as a constituent of free preribosomal particles but is absent from cytoplasmic ribosomes. Analyses of immunocomplexes isolated from cellular extracts with an NO52-specific antibody by MALDI mass spectrometry further confirmed the interaction of protein NO52 with various ribosomal proteins as well as with a distinct set of non-ribosomal nucleolar proteins. The dependence of the nucleolar accumulation of the protein on ongoing rRNA transcription and the cellular metabolic state strongly suggest that protein NO52 is directly involved in ribosome biogenesis, most likely during the assembly process of preribosomal particles.

Developmental role of HMGN proteins in Xenopus laevis

HMGN proteins are architectural chromatin proteins that reduce the compaction of the chromatin fiber, facilitate access to nucleosomes and modulate replication and transcription processes. Here we demonstrate that in Xenopus laevis, the expression and cellular location of the HMGN proteins are developmentally regulated and that their misexpression leads to gross developmental defects in post-blastula embryos. HMGN transcripts and proteins are present throughout oogenesis; however, the proteins stored in the cytoplasm are not associated with lampbrush chromosomes, and are rapidly degraded when oocytes mature into eggs. During embryogenesis, HMGN expression is first detected in blastula stages and progresses to a tissue-specific expression reaching relative high levels in the mesodermal and neuroectodermal regions of tadpoles. Only after midblastula transition (MBT), alterations in the HMGN levels by either microinjection of recombinant proteins or by morpholino-antisense oligo treatments produced embryos with imperfectly closed blastopore, distorted body axis and showed abnormal head structures. Analyses of animal cap explants indicated that HMGN proteins are involved in the regulation of mesoderm specific genes. In addition, HMGN misexpression caused altered expression of specific genes at MBT rather than global changes of transcription rates. Our results demonstrate that proper embryonic development of Xenopus laevis requires precisely regulated levels of HMGN proteins and suggest that these nucleosomal binding proteins modulate the expression of specific genes.

Actin- and protein-4.1-containing filaments link nuclear pore complexes to subnuclear organelles inXenopusoocyte nuclei

We imaged the interiors of relatively intact Xenopus oocyte nuclei by field emission scanning electron microscopy (feSEM) and visualized a network of filaments that attach to nuclear pore complexes and extend throughout the nucleus. Within the nucleus, these `pore-linked filaments' (PLFs) were embedded into spherical structures 100 nm to ∼5 μm in diameter. A subset of spheres was identified as Cajal bodies by immuno-gold labeling; the rest were inferred to be nucleoli and snurposomes both of which are abundant in Xenopus oocyte nuclei. Most PLFs were independent of chromatin. The thickness of a typical PLF was 40 nm (range, ∼12-100 nm), including the 4 nm chromium coat. PLFs located inside the nucleus merged, bundled and forked, suggesting architectural adaptability. The PLF network collapsed upon treatment with latrunculin A, which depolymerizes actin filaments. Jasplakinolide, which stabilizes actin filaments, produced PLFs with more open substructure including individual filaments with evenly-spaced rows of radially projecting short filaments. Immuno-gold labeling of untreated oocyte nuclei showed that actin and protein 4.1 each localized on PLFs. Protein 4.1-gold epitopes were spaced at ∼120 nm intervals along filaments, and were often paired (∼70 nm apart) at filament junctions. We suggest that protein 4.1 and actin contribute to the structure of a network of heterogeneous filaments that link nuclear pore complexes to subnuclear organelles, and discuss possible functions for PLFs in nuclear assembly and intranuclear traffic.

Distribution of XCAP-E and XCAP-D2 in the Xenopus oocyte nucleus

Several antibodies were used to examine the distribution of two condensin members, XCAP-E and XCAP-D2, in the nucleus of Xenopus oocytes. XCAP-D2 was found to be associated with the lampbrush chromosomes. The chromosomal regions containing XCAP-D2 correspond precisely to domains of highly compacted chromatin, suggesting a direct contribution of XCAP-D2 in meiotic chromatin organization. In contrast, XCAP-E was found to be absent from chromosomes but was detected at a high concentration in the granular component of nucleoli. The subnucleolar localization of XCAP-E was further confirmed by double labeling using several nucleolar protein markers. The fate of nucleolar XCAP-E was also followed when changes in the nucleoli morphology were artificially induced. The apparent exclusion of XCAP-E from the ribosomal DNA and its tight association with the granular component in all preparations suggest that it might be sequestrated in nucleoli during early stages of meiosis. Interestingly, both XCAP-D2 and XCAP-E were also detected in Cajal bodies, which are organelles suspected to play a role in the assembly/modification of the RNA transcription and processing machinery. The presence of two condensins in CBs might extend such a role of assembly to chromatin macromolecular components as well.

NO66, a highly conserved dual location protein in the nucleolus and in a special type of synchronously replicating chromatin

It has recently become clear that the nucleolus, the most prominent nuclear subcompartment, harbors diverse functions beyond its classic role in ribosome biogenesis. To gain insight into nucleolar functions, we have purified amplified nucleoli from Xenopus laevis oocytes using a novel approach involving fluorescence-activated cell sorting techniques. The resulting protein fraction was analyzed by mass spectrometry and used for the generation of monoclonal antibodies directed against nucleolar components. Here, we report the identification and molecular characterization of a novel, ubiquitous protein, which in most cell types appears to be a constitutive nucleolar component. Immunolocalization studies have revealed that this protein, termed NO66, is highly conserved during evolution and shows in most cells analyzed a dual localization pattern, i.e., a strong enrichment in the granular part of nucleoli and in distinct nucleoplasmic entities. Colocalizations with proteins Ki-67, HP1alpha, and PCNA, respectively, have further shown that the staining pattern of NO66 overlaps with certain clusters of late replicating chromatin. Biochemical experiments have revealed that protein NO66 cofractionates with large preribosomal particles but is absent from cytoplasmic ribosomes. We propose that in addition to its role in ribosome biogenesis protein NO66 has functions in the replication or remodeling of certain heterochromatic regions.

Nucleolomics: an inventory of the nucleolus

In the January 8 issue of Current Biology, two papers from the Lamond and Mann laboratories describe the largest proteomics analysis to date of a cellular compartment, the nucleolus. As a byproduct of this tour de force, a novel nuclear compartment, the paraspeckles, was identified.