Functional interaction of Puralpha with the Cdk2 moiety of cyclin A/Cdk2

Puralpha is a sequence-specific single-stranded nucleic acid-binding protein and a member of the highly conserved Pur family. Puralpha has been shown to colocalize with cyclin A/Cdk2 and to coimmunoprecipitate with cyclin A during S-phase. Here we show that this interaction is mediated by a specific affinity of Puralpha for Cdk2. In pull-down assays GST-Puralpha efficiently binds Cdk2 and Cdk1, binds Cdk4 less efficiently, and does not display binding to Cdk6. Puralpha stimulates several-fold the phosphorylation in vitro of histone H1 by cyclin A/Cdk2, produced from baculovirus constructs. Double chromatin immunoprecipitation using antibodies to Cdk2 and Puralpha reveals that both proteins colocalize in HeLa cells to DNA segments upstream of the c-MYC gene. Pur family member Purgamma colocalizes with Cdk2 to a specific DNA segment in this region.     

Cdk5 activity is required for Purkinje cell dendritic growth in cell‐autonomous and non‐cell‐autonomous manners

Cyclin‐dependent kinase 5 (Cdk5) is recognized as a unique member among other Cdks due to its versatile roles in many biochemical processes in the nervous system. The proper development of neuronal dendrites is required for the formation of complex neural networks providing the physiological basis of various neuronal functions. We previously reported that sparse dendrites were observed on cultured Cdk5‐null Purkinje cells and Purkinje cells in Wnt1^cre‐mediated Cdk5 conditional knockout (KO) mice. In the present study, we generated L7^cre‐mediated p35; p39 double KO (L7^cre‐p35^f/f; p39^–/–) mice whose Cdk5 activity was eliminated specifically in Purkinje cells of the developing cerebellum. Consequently, these mice exhibited defective Purkinje cell migration, motor coordination deficiency and a Purkinje dendritic abnormality similar to what we have observed before, suggesting that dendritic growth of Purkinje cells was cell‐autonomous in vivo . We found that mixed and overlay cultures of WT cerebellar cells rescued the dendritic deficits in Cdk5‐null Purkinje cells, however, indicating that Purkinje cell dendritic development was also supported by non‐cell‐autonomous factors. We then again rescued these abnormalities in vitro by applying exogenous brain‐derived neurotrophic factor (BDNF). Based on the results from culture experiments, we attempted to rescue the developmental defects of Purkinje cells in L7^cre‐p35^f/f; p39^–/– mice by using a TrkB agonist. We observed partial rescue of morphological defects of dendritic structures of Purkinje cells. These results suggest that Cdk5 activity is required for Purkinje cell dendritic growth in cell‐autonomous and non‐cell‐autonomous manners. © 2017 Wiley Periodicals, Inc. Develop Neurobiol 77: 1175–1187, 2017     

C9orf10 protein, a novel protein component of Puralpha-containing mRNA-protein particles (Puralpha-mRNPs): characterization of developmental and regional expressions in the mouse brain.

Puralpha has been implicated in mRNA transport and translation in neurons. We previously reported that Puralpha is a component of mRNA/protein complexes (Puralpha-mRNPs) with several other proteins. Among them, we found the C9orf10 (Homo sapiens chromosome 9 open reading frame 10) protein, which was recently characterized as a component of RNA-containing structures. However, C9orf10 itself remains poorly understood. To characterize C9orf10 expression at the protein level, we raised an antibody against C9orf10 and compared the spatial and developmental expressions of this protein and Puralpha in the mouse brain. C9orf10 was expressed as early as embryo stage 12, whereas Puralpha was expressed from 5 days after birth. In adults, C9orf10 expression was most prominent in the hippocampus, caudate putamen, cerebral cortex, and cerebellum, unlike the uniform distribution of Puralpha. C9orf10-positive cells also showed immunoreactivity to Puralpha. C9orf10 expression was restricted to neurons, judging by the immunoreactivity to neuron-specific nuclear protein or CaM kinase II. These observations suggest an accessory role of C9orf10 for Puralpha in a limited brain region in addition to other possible functions that have not yet been determined.     

A binding site for Pur alpha and Pur beta is structurally unstable and is required for replication in vivo from the rat aldolase B origin

The rat aldolase B promoter acts as a replication origin in vivo, as well as an autonomously replicating sequence (ARS). Here, we examined roles of a polypurine stretch (site PPu) in this origin, which is indispensable to the ARS activity. Purification of site PPu-binding protein revealed that site PPu binds Puralpha and Purbeta, i.e., single-stranded DNA-binding proteins whose roles in replication have been implicated, but less clear. Biochemical analyses showed that site PPu even in a longer DNA fragment is unstable in terms of double-helix, implying that Puralpha/beta may stabilize single-stranded state. Deletion of site PPu from the origin DNA, which was ectopically positioned in the mouse chromosome, significantly reduced replicator activity. Chromatin immunoprecipitation experiments showed that deletion of site PPu abolishes binding of the Puralpha/beta proteins to the origin. These observations suggest functional roles of site PPu and Puralpha/beta proteins in replication initiation.     

The histidine triad protein Hint is not required for murine development or Cdk7 function

The histidine triad (HIT) protein Hint has been found to associate with mammalian Cdk7, as well as to interact both physically and genetically with the budding yeast Cdk7 homologue Kin28. To study the function of Hint and to explore its possible role in modulating Cdk7 activity in vivo, we have characterized the expression pattern of murine Hint and generated Hint-deficient (Hint(-/-)) mice. Hint was widely expressed during mouse development, with pronounced expression in several neuronal ganglia, epithelia, hearts, and testes from embryonic day 15 onward. Despite this widespread expression, disruption of Hint did not impair murine development. Moreover, Hint-deficient mice had a normal life span and were apparently healthy. Histological examination of tissues with high Hint expression in wild-type animals did not show signs of abnormal pathology in Hint(-/-) mice. Functional redundancy within the HIT family was addressed by crossing Hint(-/-) mice with mice lacking the related HIT protein, Fhit, and by assaying the expression levels of the HIT protein gene family members Hint2 and Hint3 in Hint(+/+) and Hint(-/-) tissues. Finally, Cdk7 kinase activity and cell cycle kinetics were found to be comparable in wild-type and Hint(-/-) mouse embryonic fibroblasts, suggesting that Hint may not be a key regulator of Cdk7 activity.     

Cdk1 and Cdk2 activity levels determine the efficiency of replication origin firing in Xenopus

In this paper, we describe how, in a model embryonic system, cyclin-dependent kinase (Cdk) activity controls the efficiency of DNA replication by determining the frequency of origin activation. Using independent approaches of protein depletion and selective chemical inhibition of a single Cdk, we find that both Cdk1 and Cdk2 are necessary for efficient DNA replication in Xenopus egg extracts. Eliminating Cdk1, Cdk2 or their associated cyclins changes replication origin spacing, mainly by decreasing frequency of activation of origin clusters. Although there is no absolute requirement for a specific Cdk or cyclin, Cdk2 and cyclin E contribute more to origin cluster efficiency than Cdk1 and cyclin A. Relative Cdk activity required for DNA replication is very low, and even when both Cdk1 and Cdk2 are strongly inhibited, some origins are activated. However, at low levels, Cdk activity is limiting for the pre-replication complex to pre-initiation complex transition, origin activation and replication efficiency. As such, unlike mitosis, initiation of DNA replication responds progressively to changes in Cdk activity at low activity levels.     

Initial phase of dendrite growth: evidence for the involvement of high molecular weight microtubule-associated proteins (HMWP) before the appearance of tubulin

It has recently been shown that high molecular weight microtubule- associated proteins (HMWP) in the brain are present in dendrites and are absent from axons (Matus et al., 1981, Proc. Natl. Acad. Sci. U. S. A. 78:3010-3014). In this study we followed the appearance of both HMWP and tubulin in the neonatal rat cerebellum by immunoperoxidase staining, concentrating particularly on comparing Purkinje cell dendrites with adjacent granule cell axons. In the axons both immunohistochemically demonstrable tubulin and structurally distinct microtubules are present at all stages of development. By contrast the Purkinje cell dendrites contain better neither tubulin nor microtubules at early stages of their growth. However, immunoperoxidase staining showed that these developing dendrites are rich in HMWP which are particularly concentrated in the dendritic distal regions. HMWP are also present as patches beneath the surface membrane of the cell body before the emergence of dendrites. Based on this data and the well- documented ability of HMWP to promote microtubule assembly, we propose the hypothesis that during the initial phase of Purkinje neuron differentiation HMWP form part of a specialized cytoskeletal structure which acts as a specifier for the development of dendrites as opposed to axons.     

Ras-induced colony formation and anchorage-independent growth inhibited by elevated expression of Puralpha in NIH3T3 cells

Levels of Puralpha, a conserved, sequence-specific single-stranded DNA and RNA binding protein, fluctuate during the cell cycle, declining at the onset of S-phase and peaking at mitosis. In early G1 Puralpha is associated with the hypophosphorylated form of the retinoblastoma protein, Rb. Microinjection of purified Puralpha into NIH3T3 cells arrests the cell cycle at either G1/S or G2/M checkpoints with distinct morphological consequences. Here we ask whether expression of Puralpha can affect colony formation and anchorage-independent growth in ras-transformed NIH3T3 cells. Two to five-fold elevated levels of Puralpha in stably-transfected cell lines retard entry into and progression through S phase in both ras-transformed and non-transformed cells. Puralpha significantly inhibits colony formation by ras-transformed cells but not by non-transformed cells. In addition, cells transfected to express Puralpha formed only about 1/5 the number of large colonies in soft agar as control-transfected cells, demonstrating a marked inhibition of anchorage-independent growth by Puralpha. Biochemical analysis of nuclear and cytoplasmic Puralpha proteins and confocal microscopic analysis of Puralpha location indicate that access of Puralpha to the nucleus is controlled by both protein modification and sequence domains within the protein. Analyses of deletion mutants identify Puralpha domains mediating nuclear exclusion, including several potential destruction motifs and a PEST sequence at aa's 215-231. In the nucleus Puralpha colocalizes with CDK2 and cyclin A. Puralpha and cyclin D1, however, do not colocalize in the nucleus. At mitosis Puralpha is visualized about the condensed chromosomes and in the cytoplasm, where it colocalizes with cyclin B1. The data indicate that the ability of Puralpha to interact with proteins regulating cell proliferation and transformation is controlled by signals that govern its intracellular localization.     

Identification of mRNA/protein (mRNP) complexes containing Puralpha,mStaufen, fragile X protein,and myosin Va and their association with rough endoplasmic reticulum equipped with a kinesin motor

Puralpha, which is involved in diverse aspects of cellular functions, is strongly expressed in neuronal cytoplasm. Previously, we have reported that this protein controls BC1 RNA expression and its subsequent distribution within dendrites and that Puralpha is associated with polyribosomes. Here, we report that, following treatment with EDTA, Puralpha was released from polyribosomes in mRNA/protein complexes (mRNPs), which also contained mStaufen, Fragile X Mental Retardation Protein (FMRP), myosin Va, and other proteins with unknown functions. As the coimmunoprecipitation of these proteins by an anti-Puralpha antibody was abolished by RNase treatment, Puralpha may assist mRNP assembly in an RNA-dependent manner and be involved in targeting mRNPs to polyribosomes in cooperation with other RNA-binding proteins. The immunoprecipitation of mStaufen- and FMRP-containing mRNPs provided additional evidence that the anti-Puralpha detected structurally or functionally related mRNA subsets, which are distributed in the somatodendritic compartment. Furthermore, mRNPs appear to reside on rough endoplasmic reticulum equipped with a kinesin motor. Based on our present findings, we propose that this rough endoplasmic reticulum structure may form the molecular machinery that mediates and regulates multistep transport of polyribosomes along microtubules and actin filaments, as well as localized translation in the somatodendritic compartment.     

Somatodendritic localization of Translin, a component of the Translin/Trax RNA binding complex

Recent studies implicating dendritic protein synthesis in synaptic plasticity have focused attention on identifying components of the molecular machinery involved in processing dendritic RNA. Although Translin was originally identified as a protein capable of binding single-stranded DNA, subsequent studies have demonstrated that it also binds RNA in vitro. Because previous studies indicated that Translin-containing RNA/single-stranded DNA binding complexes are highly enriched in brain, we and others have proposed that it may be involved in dendritic RNA processing. To assess this possibility, we have conducted studies aimed at defining the localization of Translin and its partner protein, Trax, in brain. In situ hybridization studies demonstrated that both Translin and Trax are expressed in neurons with prominent staining apparent in cerebellar Purkinje cells and neuronal layers of the hippocampus. Subcellular fractionation studies demonstrated that both Translin and Trax are highly enriched in the cytoplasmic fraction compared with nuclear extracts. Furthermore, immunohistochemical studies with Translin antibodies revealed prominent staining in Purkinje neuron cell bodies that extends into proximal and distal dendrites. A similar pattern of somatodendritic localization was observed in hippocampal and neocortical pyramidal neurons. These findings demonstrate that Translin is expressed in neuronal dendrites and therefore support the hypothesis that the Translin/Trax complex may be involved in dendritic RNA processing.     

Distribution of Kiaa0319-like immunoreactivity in the adult mouse brain--a novel protein encoded by the putative dyslexia susceptibility gene KIAA0319-like

Kiaa0319L is a novel protein encoded by a recently discovered gene KIAA0319-like(L) that may be associated with reading disability. Little is known about the characteristics of this protein and its distribution in the brain. We investigated here expression of this protein in adult mice, using an antibody specific for human and rodent Kiaa0319L. In the brain, Kiaa0319L was localized strongly in the olfactory bulb, and strong expression was found in other regions, including hippocampus, cerebellum, diencephalon and the cerebral cortex. Immunohistochemistry confirmed expression in these brain regions, and showed further that the protein was expressed preferentially in neurons in layer IV and VI of the neocortex, CA1 and CA2 subfields of the hippocampus and a subpopulation of neurons in CA3 and dentate gyrus. Furthermore, the protein was confined to dendrites of CA1 neurons in the stratum radiatum, but not those in the stratum oriens, and in astrocytes within the hippocampus. In the cerebellum, the protein was observed in the molecular layer and a fraction of Purkinje neurons. These findings confirmed expression of Kiaa0319L in brain regions that are involved in reading performance, supporting its possible involvement in reading disability. The specific patterns of localization in the neocortex, hippocampus and cerebellum suggest further that this protein may be related to other biological processes in a subpopulation of neurons within these regions, eg. formation and maintenance of polarity in the neuron.     

p21 Inhibits Cdk1 in the absence of Cdk2 to maintain the G1/S phase DNA damage checkpoint

Cdk1 was proposed to compensate for the loss of Cdk2. Here we present evidence that this is possible due to premature translocation of Cdk1 from the cytoplasm to the nucleus in the absence of Cdk2. We also investigated the consequence of loss of Cdk2 on the maintenance of the G1/S DNA damage checkpoint. Cdk2(-/-) mouse embryonic fibroblasts in vitro as well as regenerating liver cells after partial hepatectomy (PH) in Cdk2(-/-) mice, arrest promptly at the G1/S checkpoint in response to gamma-irradiation due to activation of p53 and p21 inhibiting Cdk1. Furthermore re-entry into S phase after irradiation was delayed in Cdk2(-/-) cells due to prolonged and impaired DNA repair activity. In addition, Cdk2(-/-) mice were more sensitive to lethal irradiation compared to wild-type and displayed delayed resumption of DNA replication in regenerating liver cells. Our results suggest that the G1/S DNA damage checkpoint is intact in the absence of Cdk2, but Cdk2 is important for proper repair of the damaged DNA.     

Is It Easy to Stop RNA Polymerase?

Cdk2 has been viewed as a key cell cycle regulator that is essential for S phase progression. The recent discovery that Cdk2 is not required for cell proliferation in mice now shows that other factors must be able to replace Cdk2 in stimulating DNA replication. Experiments performed in Xenopus egg extracts identify the mitotic protein kinases Cdk1/Cyclin B and Cdk1/Cyclin A as likely candidates. These observations raise the intriguing possibility that Cdk1 normally participates in genome duplication in wild type cells.     

Cdk1: unsung hero of S phase?

Cdk2 has been viewed as a key cell cycle regulator that is essential for S phase progression. The recent discovery that Cdk2 is not required for cell proliferation in mice now shows that other factors must be able to replace Cdk2 in stimulating DNA replication. Experiments performed in Xenopus egg extracts identify the mitotic protein kinases Cdk1/Cyclin B and Cdk1/Cyclin A as likely candidates. These observations raise the intriguing possibility that Cdk1 normally participates in genome duplication in wild type cells.