The Genomic Structure of ZNF198 and Location of Breakpoints in the t(8;13) Myeloproliferative Syndrome

The t(8;13)(p11;q12) is the most common translocation associated with the 8p11 myeloproliferative syndrome and results in an identical mRNA fusion between ZNF198 at 13q12 and FGFR1 at 8p11 in all cases thus far reported. ZNF198 is a widely expressed gene that is predicted to encode a 1377-amino-acid protein with five Zn finger-related motifs known as MYM domains. To determine the genomic DNA structure of ZNF198, we employed bubble PCR from PAC clones with a panel of gene-specific primers. Sequencing of these products revealed that ZNF198 consists of 26 exons with the initiation codon located in exon 4. The t(8;13) results in a consistent mRNA fusion of ZNF198 exon 17 to FGFR1 exon 9. Notable features of the structure of ZNF198 include three noncanonical GC donor splice sites and the presence of an alternatively spliced intron within exon 4. Amplification of genomic DNA from six t(8;13) patients with primers to ZNF198 exon 17 and FGFR1 exon 9 yielded patient-specific products ranging in size from 500 bp to 2.5 kb, indicating that the positions of the breakpoints in the t(8;13) are tightly clustered. The positions of the six t(8;13) breakpoints were determined and found to be distributed across ZNF198 intron 17 and FGFR1 intron 8 with no apparent subclustering. No consistent sequence motifs, repeats, or topoisomerase II cleavage sites were found at or near the breakpoints. It remains unclear why the t(8;13) translocation breakpoints occur within such small genomic regions, and it is possible that strict ZNF198–FGFR1 coding requirements restrict the positions of the breakpoints.     

Characterization of the Drosophila Group Ortholog to the Amino-Terminus of the Alpha-Thalassemia and Mental Retardation X-Linked (ATRX) Vertebrate Protein

The human ATRX gene encodes hATRX, a chromatin-remodeling protein harboring an helicase/ATPase and ADD domains. The ADD domain has two zinc fingers that bind to histone tails and mediate hATRX binding to chromatin. dAtrx, the putative ATRX homolog in Drosophila melanogaster, has a conserved helicase/ATPase domain but lacks the ADD domain. A bioinformatic search of the Drosophila genome using the human ADD sequence allowed us to identify the CG8290 annotated gene, which encodes three ADD harboring- isoforms generated by alternative splicing. This Drosophila ADD domain is highly similar in structure and in the amino acids which mediate the histone tail contacts to the ADD domain of hATRX as shown by 3D modeling. Very recently the CG8290 annotated gene has been named dadd1. We show through pull-down and CoIP assays that the products of the dadd1 gene interact physically with dAtrx_L and HP1a and all of them mainly co-localize in the chromocenter, although euchromatic localization can also be observed through the chromosome arms. We confirm through ChIP analyses that these proteins are present in vivo in the same heterochromatic regions. The three isoforms are expressed throughout development. Flies carrying transheterozygous combinations of the dadd1 and atrx alleles are semi-viable and have different phenotypes including the appearance of melanotic masses. Interestingly, the dAdd1-b and c isoforms have extra domains, such as MADF, which suggest newly acquired functions of these proteins. These results strongly support that, in Drosophila, the atrx gene diverged and that the dadd1-encoded proteins participate with dAtrx in some cellular functions such as heterochromatin maintenance.     

The Problem of Mental Retardation (A Tentative Working Hypothesis)

Within the general problem of mental retardation, the focus has traditionally been on the child's intellectual inadequacy, his feeblemindedness. This is entrenched in the very term used to designate these children, who are usually called feebleminded, or mentally retarded. All the other aspects of the personality of such a child are usually seen as phenomena arising secondarily as a function of the basic intellectual defect. Many investigators do not even see any essential affective and volitional differences between these children and normal children. …     

Cells Lacking the Fragile X Mental Retardation Protein (FMRP) have Normal RISC Activity but Exhibit Altered Stress Granule Assembly

The fragile X mental retardation protein (FMRP) is an RNA-binding protein involved in the mRNA metabolism. The absence of FMRP in neurons leads to alterations of the synaptic plasticity, probably as a result of translation regulation defects. The exact molecular mechanisms by which FMRP plays a role in translation regulation have remained elusive. The finding of an interaction between FMRP and the RNA interference silencing complex (RISC), a master of translation regulation, has suggested that both regulators could be functionally linked. We investigated here this link, and we show that FMRP exhibits little overlap both physically and functionally with the RISC machinery, excluding a direct impact of FMRP on RISC function. Our data indicate that FMRP and RISC are associated to distinct pools of mRNAs. FMRP, unlike RISC machinery, associates with the pool of mRNAs that eventually goes into stress granules upon cellular stress. Furthermore, we show that FMRP plays a positive role in this process as the lack of FMRP or a point mutant causing a severe fragile X alter stress granule formation. Our data support the proposal that FMRP plays a role in controlling the fate of mRNAs after translation arrest.     

The Role of the Primary Physician in Mental Retardation

Practicing physicians are called upon with increased frequency for the diagnosis and treatment of the mentally retarded. The syndrome is a complex health, education, social and vocational problem. Classification is generally based on the degree of impairment, the causation and the symptomatology. There are two major types of mental retardation. In one, the impairment is more severe and concomitant physical signs are frequent. In the other, the impairment is mild and somatic signs are absent.Diagnosis calls for careful developmental history, examination and a judicious use of laboratory and other tests. Early diagnosis and the establishment of cause have important therapeutic and preventive implications. Counseling of parents is an essential part of clinical work.     

智力低下相关蛋白(FXR1P)与CMAS相互作用的生物学效应研究

脆性X综合征(FXS)是一种遗传性智力低下疾病,其发病率仅次于21三体综合征．脆性X智力低下蛋白(FMRP)是FXS的关键性致病因子,该蛋白由脆性X智力低下基因1(FMR1)编码所得．FMR1在神经肌肉和睾丸组织中广泛表达．脆性X相关蛋白1(FXR1P)则是由FMR1的同源基因脆性X相关基因1(FXR1)编码所得,并且与蛋白质和RNAs之间存在着相互作用．许多疾病都涉及到FXR1表达的改变．为了了解FXR1P与CMAS(胞嘧啶单核苷酸-N-乙酰神经氨酸合成酶)相互作用所产生的的生物学效应,我们构建了FXR1的过表达载体,并观察其在PC12细胞(大鼠鼠肾上腺嗜铬细胞瘤细胞)和VSMC(血管平滑肌细胞)中的表达以及继而对于细胞形态和CMAS活性相关的许多细胞指标的效应．我们证实,FXR1基因的过表达可以提高PC12细胞中CMAS的活性,并对于该类细胞的生长提供一定程度的保护作用．PC12细胞是一种较为常见的用于研究神经系统疾病的细胞系．结论：我们推测FXR1P是一个组织特异调节因子,可以改变PC12细胞而非VSMC细胞中神经节苷酯(GM1)的浓度．     

Characterization of the Major Capsid Genes (g23) of T4-Type Bacteriophages in the Wetlands of Northeast China

To obtain genetic information and to evaluate the composition of T4-type bacteriophage (phage) communities in wetlands, environmental soil and water DNAs were obtained from two natural wetlands dominated by Carex lasiocarpa and Deyeuxia angustifolia plant species, and a neighboring paddy field in Sanjiang plain of northeast China. The biomarker gene of g23, which encodes the major capsid protein of T4-type phages, was amplified with primers MZIA1bis and MZIA6, and the PCR products were cloned and sequenced. In total, 96 and 50 different g23 clones were obtained from natural wetlands and a paddy field, respectively. A larger number of clones with low levels of identity to known sequences were found in water than in soil both in the natural wetlands and the paddy field, suggesting that many of T4-type phages in wetland water and paddy floodwater in Sanjiang plain are uncharacterized. Phylogenetic analyses showed that the g23 clones in natural wetlands, irrespective of water and soil, were distinctly different from those in marine waters, lake waters, and upland black soils, but were similar to those in paddy fields. The UniFrac analysis of g23 assemblages indicated that T4-type phage community compositions were different between soils and waters, and also were different between the natural wetlands and the paddy field. In general, the global analysis of g23 clone assemblages demonstrated that T4-type phage community compositions were different among natural wetlands, marines, lakes, paddy fields, and upland black soils.     

Characterization of the Antiviral Activity for Influenza Viruses M1 Zinc Finger Peptides

We sought to investigate the cellular uptake and antiviral activity for the M1 zinc finger peptides derived from influenza A and influenza B viruses in vitro. No cellular uptake was detected by fluorescent microscopy for the synthetic zinc finger peptides. When flanked to a cell permeable peptide Tp10, the zinc finger recombinant proteins were efficiently internalized by MDCK cells. However, no antiviral activity was detected against homologous or heterologous virus infections for the synthetic peptides or the Tp10-flanked recombinant proteins, regardless treated with or without Zn²⁺. Nevertheless, MDCK cell constitutively expressing the M1 zinc finger peptides in cell nuclei potently inhibited replication of homologous, but not heterologous influenza viruses. Adenoviral vector delivered M1 zinc finger peptides also exhibited potent antiviral activity against homologous viruses challenge. Transduction at 100 PFU dose of recombinant adenovirus efficiently protected 99% of the cells from 100 TCID₅₀ of different virus infections for both peptides. These results brought new insight to the antiviral researches against influenza virus infections.     

Proposed Mechanism of Inheritance and Expression of the Human Fragile-X Syndrome of Mental Retardation

A mechanism is proposed for the inheritance and expression of the fragile-X-linked syndrome of mental retardation in humans. Two independent events are required for expression of the syndrome: the fragile-X mutation, and X chromosome inactivation in pre-oogonial cells. The fragile-X mutation at site Xq27 has little or no effect until the chromosome is inactivated in a female as part of the process of dosage compensation. At a stage where the inactivated X chromosome would normally be reactivated in preparation for oogenesis, the mutation results in a local block to the reactivation process. This block to reactivation leads to mental retardation in progeny by reducing the level of products from the unreactivated Xq27 region in male cells, and, for a heterozygous female, in somatic cells in which the normal X chromosome has been inactivated. Published data relevant to this proposed mechanism are discussed.     

G-Protein Coupled Receptor 83 (GPR83) Signaling Determined by Constitutive and Zinc(II)-Induced Activity

The G-protein coupled receptor 83 (GPR83) is an orphan G-protein coupled receptor for which the natural ligand(s) and signaling pathway(s) remain to be identified. Previous studies suggest a role of GPR83 in the regulation of thermogenesis and the control of circulating adiponectin. The aim of this study was to gain insights into the molecular underpinnings underlying GPR83 signaling. In particular, we aimed to assess the underlying G-protein activated signaling pathway of GPR83 and how this pathway is affected by mutational activation and zinc(II) challenge. Finally, we assessed the capacity of GPR83 for homodimerization. Our results show for the first time that mouse (m) GPR83 has high basal Gq/11 activity without affecting Gi or Gs signaling. Furthermore, we found that, under physiological conditions, zinc(II) (but not calcium(II) and magnesium(II)) potently activates mGPR83, thus identifying zinc(II) as an endogenous molecule with agonistic capability to activate mGPR83. In line with the observation that zinc(II)-ions activate mGPR83, we identified a cluster of ion-binding sensitive amino acids (e.g. His145, His204, Cys207, Glu217) in an activation sensitive receptor region of mGPR83. The occurrence of a constitutive activating mutant and a zinc(II)-binding residue at the N-terminal part corroborate the importance of this region in mGPR83 signal regulation. Finally, our results indicate that mGPR83 forms homodimers, which extend the current knowledge and molecular facets of GPR83 signaling.