Aberrant protein folding beyond the capacity of endoplasmic reticulum (ER) quality control leads to stress response in the ER. The Lys-Asp-Glu-Leu (KDEL) receptor, a retrieval receptor for ER chaperones in the early secretory pathway, contributes to ER quality control. To elucidate the function of the KDEL receptor in vivo, we established transgenic mice expressing a mutant KDEL receptor. We found that the mutant KDEL receptor sensitized cells to ER stress and that the mutant mice developed dilated cardiomyopathy. Ultrastructural analyses revealed expanded sarcoplasmic reticulums and protein aggregates that obstructed the adjacent transverse tubules of the mutant cardiomyocytes. Cardiomyocytes from the mutant mice were sensitive to ER stress when treated with tunicamycin and showed a functional defect in the L-type Ca 2؉ current. We observed ubiquitinated protein aggregates, enhanced expression of CHOP (a death-related transcriptional factor expressed upon ER stress), and apoptosis in the mutant hearts. These findings suggest that impairment of the KDEL receptor disturbs ER quality control, resulting in accumulation of misfolded proteins in the ER in an in vivo system, and that the dilated cardiomyopathy found in the mutant KDEL receptor transgenic mice is associated with ER stress.The endoplasmic reticulum (ER) provides a folding environment for newly synthesized secretory and membrane proteins (10). Aberrant protein folding due to extracellular stimuli, such as ischemia and oxidative stress, and genetic mutation lead to the accumulation of misfolded proteins in the ER, which in turn evokes the unfolded protein response (43), which reduces the amount of misfolded proteins by inducing the production of ER chaperones that promote protein folding, reducing general protein synthesis (16) and enhancing the degradation of misfolded proteins via a ubiquitin-proteasome system termed ER-associated degradation (7, 9, 60). The persistent accumulation of misfolded proteins beyond the capacity of ER quality control causes cellular dysfunction and cell death (24,25,46). This process is involved in diverse human disorders, including diabetes mellitus (14, 42) and neurodegenerative diseases such as Alzheimer's (23) and Parkinson's (20).Misfolded proteins had been believed to remain in the ER, but recent genetic analyses in Saccharomyces cerevisiae have indicated that the unfolded protein response involves the whole secretory pathway (56) and that some misfolded proteins require transport between the ER and the Golgi complex for ER-associated degradation (17,41,53,58). In addition, certain misfolded proteins in mammalian cells have also been reported to exit the ER and recycle between the ER and post-ER compartments, associating with ER chaperones. The KDEL receptor mediates this retrieval, suggesting that the secretion of misfolded proteins from the ER and their retrieval may contribute to ER quality control (12, 62).The KDEL receptor has been identified as a retrieval receptor for luminal ER chaperones that have a carboxyl-te...
The Polycomb group (PcG) gene products form multimeric protein complexes and contribute to anteriorposterior (A-P) specification via the transcriptional regulation of Hox cluster genes. The Drosophila polyhomeotic genes and their mammalian orthologues, Phc1, Phc2, and Phc3, encode nuclear proteins that are constituents of evolutionarily conserved protein complexes designated class II PcG complexes. In this study, we describe the generation and phenotypes of Phc2-deficient mice. We show posterior transformations of the axial skeleton and premature senescence of mouse embryonic fibroblasts associated with derepression of Hox cluster genes and Cdkn2a genes, respectively. Synergistic actions of a Phc2 mutation with Phc1 and Rnf110 mutations during A-P specification, coimmunoprecipitation of their products from embryonic extracts, and chromatin immunoprecipitation by anti-Phc2 monoclonal antibodies suggest that Hox repression by Phc2 is mediated through the class II PcG complexes, probably via direct binding to the Hox locus. The genetic interactions further reveal the functional overlap between Phc2 and Phc1 and a strict dose-dependent requirement during A-P specification and embryonic survival. Functional redundancy between Phc2 and Phc1 leads us to hypothesize that the overall level of polyhomeotic orthologues in nuclei is a parameter that is critical in enabling the class II PcG complexes to exert their molecular functions.
SUMMARYDuring meiosis, specific histone modifications at pericentric heterochromatin (PCH), especially histone H3 tri-and dimethylation at lysine 9 (H3K9me3 and H3K9me2, respectively), are required for proper chromosome interactions. However, the molecular mechanism by which H3K9 methylation mediates the synapsis is not yet understood. We have generated a Cbx3-deficient mouse line and performed comparative analysis on Suv39h1/h2-, G9a-and Cbx3-deficient spermatocytes. This study revealed that H3K9me2 at PCH depended on Suv39h1/h2-mediated H3K9me3 and its recognition by the Cbx3 gene product HP1. We further found that centromere clustering and synapsis were commonly affected in G9a-and Cbx3-deficient spermatocytes. These genetic observations suggest that HP1/G9a-dependent PCH-mediated centromere clustering is an axis for proper chromosome interactions during meiotic prophase. We propose that the role of the HP1/G9a axis is to retain centromeric regions of unpaired homologous chromosomes in close alignment and facilitate progression of their pairing in early meiotic prophase. This study also reveals considerable plasticity in the interplay between different histone modifications and suggests that such stepwise and dynamic epigenetic modifications may play a pivotal role in meiosis.
A previous study has demonstrated that the soleus H reflex is facilitated in association with voluntary teeth clenching in proportion with biting force in humans. The present study tried to elucidate the functional significance of this facilitation of the soleus H reflex, by examining 1) whether the facilitation of the H reflex is reciprocal or nonreciprocal between the ankle extensors and flexors and 2) whether the reciprocal Ia inhibition of crural muscles is facilitated or depressed in association with voluntary teeth clenching. The H reflex of the pretibial muscles was evoked by stimulation of the common peroneal nerve in seven healthy subjects with no oral dysfunction. The pretibial H reflex was facilitated in association with voluntary teeth clenching in a force-dependent manner. The facilitation started preceding the onset of electromyographic activity of the masseter muscle. Stimulation of the common peroneal nerve at low intensities subthreshold for evoking the M wave of the pretibial muscles inhibited the soleus H reflex after a short latency corresponding with a disynaptic inhibition, indicating that the reciprocal Ia inhibition was depressed in association with voluntary teeth clenching. Thus, the present study has shown that voluntary teeth clenching evokes a nonreciprocal facilitation of ankle extensor and flexor muscles and attenuated reciprocal Ia inhibition from the pretibial muscles to the soleus muscle. It is concluded that voluntary teeth clenching contributes to improve stability of stance rather than smoothness of movements.
Homeodomain-interacting protein kinase 1 (Hipk1), 2, and 3 genes encode evolutionarily conserved nuclear serine/threonine kinases, which were originally identified as interacting with homeodomain-containing proteins. Hipks have been repeatedly identified as interactors for a vast range of functional proteins, including not only transcriptional regulators and chromatin modifiers but also cytoplasmic signal transducers, transmembrane proteins, and the E2 component of SUMO ligase. Gain-of-function experiments using cultured cells indicate growth regulatory roles for Hipks on receipt of morphogenetic and genotoxic signals. However, Hipk1 and Hipk2 singly deficient mice were grossly normal, and this is expected to be due to a functional redundancy between Hipk1 and Hipk2. Therefore, we addressed the physiological roles of Hipk family proteins by using Hipk1 Hipk2 double mutants. Hipk1 Hipk2 double homozygotes are progressively lost between 9.5 and 12.5 days postcoitus and frequently fail to close the anterior neuropore and exhibit exencephaly. This is most likely due to defective proliferation in the neural fold and underlying paraxial mesoderm, particularly in the ventral region, which may be attributed to decreased responsiveness to Sonic hedgehog signals. The present study indicated the overlapping roles for Hipk1 and Hipk2 in mediating cell proliferation and apoptosis in response to morphogenetic and genotoxic signals during mouse development.Homeodomain-interacting protein kinases (HIPKs) compose an evolutionarily conserved protein family in eukaryotes (37). Based on database screening, it appears that three closely related homologous genes encoding Hipks are conserved in vertebrates, including humans, mice, dogs, cows, and frogs (H. Koseki, unpublished). Mammalian HIPK1, HIPK2, and HIPK3 proteins were originally identified as nuclear protein kinases that function as corepressors for various homeodomain-containing transcriptional regulators, at least in part by forming a complex with Groucho and a histone deacetylase complex (7, 37). There is extensive structural similarity exhibited by the HIPKs with respect to their protein kinase domains, homeoprotein interaction domains, PEST sequences, and C-terminal regions enriched by tyrosine and histidine (YH domains). Although HIPK proteins are mainly found in the nucleus with a novel dot-like subnuclear distribution, which partially overlaps promyelocytic leukemia (PML) nuclear bodies, they are nevertheless also found in the cytoplasm (16,44,46). HIPKs have been consistently identified as interactors for a vast range of functional proteins, including not only transcriptional regulators and chromatin modifiers but also cytoplasmic signal transducers, transmembrane proteins, and the E2 component of SUMO ligase
The product of the Scmh1 gene, a mammalian homolog of Drosophila Sex comb on midleg, is a constituent of the mammalian Polycomb repressive complexes 1 (Prc1). We have identified Scmh1 as an indispensable component of the Prc1. During progression through pachytene, Scmh1 was shown to be excluded from the XY body at late pachytene, together with other Prc1 components such as Phc1, Phc2, Rnf110 (Pcgf2), Bmi1 and Cbx2. We have identified the role of Scmh1 in mediating the survival of late pachytene spermatocytes. Apoptotic elimination of Scmh1 -/-spermatocytes is accompanied by the preceding failure of several specific chromatin modifications at the XY body, whereas synapsis of homologous autosomes is not affected. It is therefore suggested that Scmh1 is involved in regulating the sequential changes in chromatin modifications at the XY chromatin domain of the pachytene spermatocytes. Restoration of defects in Scmh1 -/-spermatocytes by Phc2 mutation indicates that Scmh1 exerts its molecular functions via its interaction with Prc1. Therefore, for the first time, we are able to indicate a functional involvement of Prc1 during the meiotic prophase of male germ cells and a regulatory role of Scmh1 for Prc1, which involves sex chromosomes.
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