Novel biallelic PCNT deletion causing microcephalic osteodysplastic primordial dwarfism type II with congenital heart defect

<正>Dear Editor,Microcephalic osteodysplastic primordial dwarfism type II(MOPD II) is characterized by developmental retardation,wherein the affected individuals usually present with intrauterine growth retardation and preterm birth (Majewski et al., 1982; Willems et al., 2010). This leads to an average weight of 1,500 g at birth and extremely restricted postnatal growth (Hall et al., 2004; Rauch, 2011). Clinical manifestations of MOPD II include microcephaly, disproportionately short stature, mild skeletal dysplasia, unusual facial features including a prominent nose, prominent eyes in infancy and early childhood, some affected individuals exhibit slightly reduced intellectual development and cerebral vascular     

Mutations that cause osteoglophonic dysplasia define novel roles for FGFR1 in bone elongation

Activating mutations in the genes for fibroblast growth factor receptors 1-3 (FGFR1-3) are responsible for a diverse group of skeletal disorders. In general, mutations in FGFR1 and FGFR2 cause the majority of syndromes involving craniosynostosis, whereas the dwarfing syndromes are largely associated with FGFR3 mutations. Osteoglophonic dysplasia (OD) is a "crossover" disorder that has skeletal phenotypes associated with FGFR1, FGFR2, and FGFR3 mutations. Indeed, patients with OD present with craniosynostosis, prominent supraorbital ridge, and depressed nasal bridge, as well as the rhizomelic dwarfism and nonossifying bone lesions that are characteristic of the disorder. We demonstrate here that OD is caused by missense mutations in highly conserved residues comprising the ligand-binding and transmembrane domains of FGFR1, thus defining novel roles for this receptor as a negative regulator of long-bone growth.     

Mutations in two Ku homologs define a DNA end-joining repair pathway in Saccharomyces cerevisiae.

DNA double-strand break (DSB) repair in mammalian cells is dependent on the Ku DNA binding protein complex. However, the mechanism of Ku-mediated repair is not understood. We discovered a Saccharomyces cerevisiae gene (KU80) that is structurally similar to the 80-kDa mammalian Ku subunit. Ku8O associates with the product of the HDF1 gene, forming the major DNA end-binding complex of yeast cells. DNA end binding was absent in ku80delta, hdf1delta, or ku80delta hdf1delta strains. Antisera specific for epitope tags on Ku80 and Hdf1 were used in supershift and immunodepletion experiments to show that both proteins are directly involved in DNA end binding. In vivo, the efficiency of two DNA end-joining processes were reduced >10-fold in ku8Odelta, hdfldelta, or ku80delta hdf1delta strains: repair of linear plasmid DNA and repair of an HO endonuclease-induced chromosomal DSB. These DNA-joining defects correlated with DNA damage sensitivity, because ku80delta and hdf1delta strains were also sensitive to methylmethane sulfonate (MMS). Ku-dependent repair is distinct from homologous recombination, because deletion of KU80 and HDF1 increased the MMS sensitivity of rad52delta. Interestingly, rad5Odelta, also shown here to be defective in end joining, was epistatic with Ku mutations for MMS repair and end joining. Therefore, Ku and Rad50 participate in an end-joining pathway that is distinct from homologous recombinational repair. Yeast DNA end joining is functionally analogous to DSB repair and V(D)J recombination in mammalian cells.     

Mutations of Ha-ras p21 that define important regions for the molecular mechanism of the SDC25 C-domain, a guanine nucleotide dissociation stimulator.

The SDC25 C-domain is a very active guanine nucleotide dissociation stimulator (GDS) isolated from Saccharomyces cerevisiae which acts equally well on Ha-ras p21 and yeast RAS2. These properties make the SDC25 C-domain a suitable tool to study the basic mechanism of a GDS. The action of the SDC25 C-domain was analysed by mutation of structurally important regions of p21. Substitutions that influence the coordination of Mg2+.GDP or the interaction of the guanine ring were found to stimulate the intrinsic dissociation of GDP and suppress the action of the SDC25 C-domain. No relevant effects were observed with mutations in the phosphate binding loop L1 or by deleting the last 23 C-terminal residues of p21. Substitutions in the switch region 1 (loop L2) and 2 (loop L4) of p21 strongly impaired the action of this GDS; however, we show that this effect is not related to a decreased affinity of the SDC25 C-domain for the mutated p21. No functional competition could be found between this GDS and the catalytic domain of the human GTPase activating protein (GAP). This indicates that GDS and GAP bind to different sites of the p21.nucleotide complex, even though the same mutations in loops L2 and L4 regions affect the activity of both effectors. Since these two regions appear not to be involved directly in the interaction with GDS, we conclude that the negative effect induced by their mutation is related to their function as switches of selective conformations during the GDP to GTP exchange reaction catalysed by GDS.     

Mutations in the alpha 1 domain of a class I gene define residues important for specific allorecognition.

Our strategy to use saturation mutagenesis to produce an unbiased collection of major histocompatibility class I mutants has resulted in unpredicted mutant phenotypes. First, we have shown data supporting our earlier work of the Dp20(Y27N) mutant. Allorecognition is altered at the clonal level while no variation in lymphocytic choriomeningitis virus (LCMV)-restricted recognition is observed. The defect does not destroy the integrity of this class I protein on the basis of three observations: (i) LCMV self-restricted recognition is not impaired, (ii) beta 2 microglobulin still associates with Dp20(Y27N) at the cell surface, and (iii) this mutant can stimulate a primary MLR. Thus, we believe Dp20(Y27N) specifically affects allorecognition, perhaps by altering self peptide associations. The Dp14(A11V;E32Q) mutant appears to interact with T cell receptors (TCR) from a cloned cytotoxic T lymphocyte, but is altered in inducing a wild type signal into the responding cell. This is presumably due to decreased interaction at the cell surface between Dp14(A11V;E32Q) and wild type-specific TCR such that variations are detected in how a cell perceives extracellular signals. Analysis of additional mutants suggests that mutant Dp163(N66S) alters the binding site for monoclonal antibodies 7-16.10 and 135, while leaving unaltered the binding site for monoclonal antibodies 34-1.2 and 11-20.3. This maps the residue responsible for 7-16.10 and 135 binding to the region of Dp163(N66S).     

Hyper-invasive mutants define a novel Pho-regulated invasion pathway in Escherichia coli

We have isolated two transposon insertion mutations of the pst–phoU operon which result in the constitutive expression of the phoA gene product, alkaline phosphatase. The two mutations also render Escherichia coli invasive towards cultured HEp-2 cells and define a novel Pho-regulated invasion pathway. The presence of the large‘invasion’plasmid derived from an entero-invasive E. coli (EIEC) clinical isolate in these mutants leads to enhanced invasiveness toward cultured HEp-2 cells, a phenomenon referred to as the‘hyper-invasive’phenotype. Transduction of a pst–phoU insertion mutation into clinical isolates of EIEC and Shigella flexneri results in constitutive PhoA expression and coupled hyper-invasiveness in the former but not the latter. We speculate that the Pho-regulated invasion pathway described here, while silent in bacteria grown in standard laboratory rich media, may become functional in the host when invasive bacteria encounter nutrient starvation and/or other related stress conditions.     

Mutations in RAD27 define a potential link between G1 cyclins and DNA replication.

The yeast Saccharomyces cerevisiae has three G1 cyclin (CLN) genes with overlapping functions. To analyze the functions of the various CLN genes, we examined mutations that result in lethality in conjunction with loss of cln1 and cln2. We have isolated alleles of RAD27/ERC11/YKL510, the yeast homolog of the gene encoding flap endonuclease 1, FEN-1.cln1 cln2 rad27/erc11 cells arrest in S phase; this cell cycle arrest is suppressed by the expression of CLN1 or CLN2 but not by that of CLN3 or the hyperactive CLN3-2. rad27/erc11 mutants are also defective in DNA damage repair, as determined by their increased sensitivity to a DNA-damaging agent, increased mitotic recombination rates, and increased spontaneous mutation rates. Unlike the block in cell cycle progression, these phenotypes are not suppressed by CLN1 or CLN2. CLN1 and CLN2 may activate an RAD27/ERC11-independent pathway specific for DNA synthesis that CLN3 is incapable of activating. Alternatively, CLN1 and CLN2 may be capable of overriding a checkpoint response which otherwise causes cln1 cln2 rad27/erc11 cells to arrest. These results imply that CLN1 and CLN2 have a role in the regulation of DNA replication. Consistent with this, GAL-CLN1 expression in checkpoint-deficient, mec1-1 mutant cells results in both cell death and increased chromosome loss among survivors, suggesting that CLN1 overexpression either activates defective DNA replication or leads to insensitivity to DNA damage.     

Mutations in a tRNA import signal define distinct receptors at the two membranes of Leishmania mitochondria

Nucleus-encoded tRNAs are selectively imported into the mitochondrion of Leishmania, a kinetoplastid protozoan. An oligoribonucleotide constituting the D stem-loop import signal of tRNA(Tyr)(GUA) was efficiently transported into the mitochondrial matrix in organello as well as in vivo. Transfer through the inner membrane could be uncoupled from that through the outer membrane and was resistant to antibody against the outer membrane receptor TAB. A number of mutations in the import signal had differential effects on outer and inner membrane transfer. Some mutants which efficiently traversed the outer membrane were unable to enter the matrix. Conversely, restoration of the loop-closing GC pair in reverse resulted in reversion of transfer through the inner, but not the outer, membrane, and binding of the RNA to the inner membrane was restored. These experiments indicate the presence at the two membranes of receptors with distinct specificities which mediate stepwise transfer into the mitochondrial matrix. The combination of oligonucleotide mutagenesis and biochemical fractionation may provide a general tool for the identification of tRNA transport factors.     

Mutations in yeast HAP2/HAP3 define a hybrid CCAAT box binding domain.

We describe a detailed genetic analysis of the DNA-binding regions in the HAP2/HAP3 CCAAT-binding heteromeric complex. The DNA-binding domain of HAP2 is shown to be a 21 residue region containing three critical histidines and three critical arginines. Mutation of an arginine at position 199 to leucine alters the DNA-binding specificity of the complex to favor CCAAC over CCAAT. Residues in HAP3 that are critical for DNA-binding comprise a short, seven amino acid region. Three different mutations in the HAP2 DNA-binding domain are suppressed by a mutation in the HAP3 DNA-binding domain. This HAP3 mutation also suppresses mutations in a different region of HAP2 which promotes subunit assembly of the complex. These findings suggest that short regions of HAP2 and HAP3 comprise a hybrid DNA-binding domain and that this domain can help hold the two subunits together in the CCAAT-binding complex.     

The Clp ATPases define a novel class of molecular chaperones

The Clp ATPases were originally identified as a regulatory component of the bacterial ATP-dependent Clp serine proteases. Proteins homologous to the Escherichia coli Clp ATPases (ClpA, B, X or Y) have been identified in every organism examined so far. Recent data suggest that the Clp ATPases are not only specificity factors which help to 'present' various protein substrates to the ClpP or other catalytic proteases, but are also molecular chaperones which can function independently of ClpP. This review discusses the recent evidence that the Clp ATPases are indeed molecular chaperones capable of either repairing proteins damaged during stress conditions or activating the initiation proteins for Mu, λ or P1 DNA replication. A mechanism is suggested to explain how the Clp ATPases 'decide' whether to repair or destroy their protein substrates.     

Mutations in the endodomain of Sindbis virus glycoprotein E2 define sequences critical for virus assembly

Envelopment of Sindbis virus at the plasma membrane is a multistep process in which an initial step is the association of the E2 protein via a cytoplasmic endodomain with the preassembled nucleocapsid. Sindbis virus is vectored in nature by blood-sucking insects and grows efficiently in a number of avian and mammalian vertebrate hosts. The assembly of Sindbis virus, therefore, must occur in two very different host cell environments. Mammalian cells contain cholesterol which insect membranes lack. This difference in membrane composition may be critical in determining what requirements are placed on the E2 tail for virus assembly. To examine the interaction between the E2 tail and the nucleocapsid in Sindbis virus, we have produced substitutions and deletions in a region of the E2 tail (E2 amino acids 408 to 415) that is initially integrated into the endoplasmic reticulum. This sequence was identified as being critical for nucleocapsid binding in an in vitro peptide protection assay. The effects of these mutations on virus assembly and function were determined in both vertebrate and invertebrate cells. Amino acid substitutions (at positions E2: 408, 410, 411, and 413) reduced infectious virus production in a position-dependent fashion but were not efficient in disrupting assembly in mammalian cells. Deletions in the E2 endodomain (delta406-407, delta409-411, and delta414-417) resulted in the failure to assemble virions in mammalian cells. Electron microscopy of BHK cells transfected with these mutants revealed assembly of nucleocapsids that failed to attach to membranes. However, introduction of these deletion mutants into insect cells resulted in the assembly of virus-like particles but no assayable infectivity. These data help define protein interactions critical for virus assembly and suggest a fundamental difference between Sindbis virus assembly in mammalian and insect cells.     

Mutations affecting early distribution of primordial germ cells in Medaka (Oryzias latipes) embryo

The development of germ cells has been intensively studied in Medaka (Oryzias latipes). We have undertaken a large-scale screen to identify mutations affecting the development of primordial germ cells (PGCs) in Medaka. Embryos derived from mutagenized founder fish were screened for an abnormal distribution or number of PGCs at embryonic stage 27 by RNA in situ hybridization for the Medaka vasa homologue (olvas). At this stage, PGCs coalesce into two bilateral vasa-expressing foci in the ventrolateral regions of the trunk after their migration and group organization. Nineteen mutations were identified from a screen corresponding to 450 mutagenized haploid genomes. Eleven of the mutations caused altered PGC distribution. Most of these alterations were associated with morphological abnormalities and could be grouped into four phenotypic classes: Class 1, PGCs dispersed into bilateral lines; Class 2, PGCs dispersed in a region more medial than that in Class 1; Class 3, PGCs scattered laterally and over the yolk sac area; and Class 4, PGCs clustered in a single median focus. Eight mutations caused a decrease in the number of PGCs. This decrease was observed in the offspring of heterozygous mothers, indicating the contribution of a maternal factor in determining PGC abundance. Taken together, these mutations should prove useful in identifying molecular mechanisms underlying the early PGC development and migration.     

Poliovirus translation: a paradigm for a novel initiation mechanism

All eukaryotic cellular mRNAs, and most viral mRNAs, are blocked at their 5' ends with a cap structure (m7GpppX, where X is any nucleotide). Poliovirus, along with a small number of other animal and plant viral mRNAs, does not contain a 5' cap structure. Since the cap structure functions to facilitate ribosome binding to mRNA, translation of polio-virus must proceed by a cap-independent mechanism. Consistent with this, recent studies have shown that ribosomes can bind to an internal region within the long 5' noncoding sequence of poliovirus RNA. Possible mechanisms for cap-independent translation are discussed. Cap-independent translation of poliovirus RNA is of major importance to the mechanism of shut-off of host protein synthesis after infection. Moreover, it is likely to play a role in determining poliovirus neurovirulence and attenuation.