人类PKNOX1基因一种新剪接型全长cDNA的克隆与表达分析

为了寻找新的Down’s综合征相关基因,利用生物信息学分析与实验技术相结合的方法,从定位于Down’s综合征关键区内(21q22．3)的EST(GenBank登录号H77399)出发,从人类睾丸组织cDNA文库内克隆到含同源盒结构域转录因子PKNOX1的一种新剪接型全长cDNA,命名为PKNOX1B,GenBank登陆号AYl42115。PKNOX1B基因跨越58．4kb,全长cDNA约2．8kb,有11个外显子和10个内含子,编码405个氨基酸残基的酸性蛋白质,分子量为44．628kDa,等电点6．28。PKNOX1B与PKNOX1的前9个外显子及9个内含子完全相同,由于PKNOX1B在第10与11外显子之间发生了差异剪接,以致其在3’端cDNA序列被截短约2kb,所编码的蛋白质在C端较PKNOX1短30个氨基酸残基。但PKNOX1B保留了与PKNOX1完全相同的同源盒结构域,因而它可能与其他含同源盒结构域基因家族成员一样参与了发育的遗传调控。RT-PCR结果显示PKNOX1B除骨髓组织外在人体组织广泛表达。在睾丸组织中PKNOX1可见5kb,2．9kb,2kb 3种转录本,而在其他组织中仅发现2个较大的转录本,2kb的转录本在睾丸组织呈现特异性的表达,它有可能参与了精子的发生过程。     

Overproduction of human Cu/Zn-superoxide dismutase in transfected cells: extenuation of paraquat-mediated cytotoxicity and enhancement of lipid peroxidation.

The 'housekeeping' enzyme Cu/Zn-superoxide dismutase (SOD-1) is encoded by a gene residing on human chromosome 21, at the region 21q22 known to be involved in Down's syndrome. The SOD-1 gene and the SOD-1 cDNA were introduced into mouse L-cells and human HeLa cells, respectively as part of recombinant plasmids containing the neoR selectable marker. Human and mouse transformants were obtained that expressed elevated levels (up to 6-fold) of authentic, enzymatically active human SOD-1. This enabled us to examine the consequences of hSOD-1 gene dosage, apart from gene dosage effects contributed by other genes residing on chromosome 21. Human and mouse cell clones that overproduce the hSOD-1 had altered properties; they were more resistant to paraquat than the parental cells and showed an increase in lipid peroxidation. The data are consistent with the possibility that gene dosage of hSOD-1 contributes to some of the clinical symptoms associated with Down's syndrome.     

Chromosomal protein HMG-14 is overexpressed in Down syndrome.

The physical phenotype of Down syndrome, one of the most prevalent genetic disorders, results from an extra copy of regions q22.1 to q22.3 of chromosome 21 in cells of affected individuals. The gene coding for chromosomal protein HMG-14 is among the limited number of genes, coding for known functions, which has been mapped to this region of chromosome 21. Here we report a gene dosage effect on the expression of HMG-14 in both cultured cells and brain tissue samples obtained from Down syndrome patients. The putative role of HMG-14 in the structure of active chromatin raises the possibility that elevated levels of this protein may be a contributing factor in the etiology of Down syndrome.     

Role of Amyloid Precursor Protein (APP) and Its Derivatives in the Biology and Cell Fate Specification of Neural Stem Cells

Amyloid precursor protein (APP) is a member of the APP family of proteins, and different enzymatic processing leads to the production of several derivatives that are shown to have distinct biological functions. APP is involved in the pathology of Alzheimer’s disease (AD), the most common neurodegenerative disorder causing dementia. Furthermore, it is believed that individuals with Down syndrome (DS) have increased APP expression, due to an extra copy of chromosome 21 (Hsa21), that contains the gene for APP. Nevertheless, the physiological function of APP remains unclear. It is known that APP plays an important role in neural growth and maturation during brain development, possibly by influencing proliferation, cell fate specification and neurogenesis of neural stem cells (NSCs). Proteolytic cleavage of APP occurs mainly via two mutually exclusive pathways, the non-amyloidogenic pathway or the amyloidogenic pathway. Other alternative pathways (η-secretase, δ-secretase and meprin pathways) have also been described for the physiological processing of APP. The different metabolites generated from these pathways, including soluble APPα (sAPPα), soluble APPβ (sAPPβ), β-amyloid (Aβ) peptides and the APP intracellular domain (AICD), have different functions determined by their structural differences, equilibrium and concentration with respect to other fragments derived from APP. This review discusses recent observations regarding possible functions of APP and its proteolytic derivatives in the biology and phenotypic specification of NSCs. This can be important for a better understanding of the pathogenesis and the development of future therapeutic applications for AD and/or DS, diseases in which alterations in neurogenesis have been described.     

多重实时荧光PCR相对定量法快速诊断唐氏综合征

为了建立一种基于多重实时荧光相对定量PCR技术并应用之于唐氏综合征分子诊断, 选择21号染色体上唐氏综合征特异区域基因片段(DSCR3)为目的基因, 以12号染色体上的磷酸甘油醛脱氢酶基因(GAPDH)为参照基因, 设计合成两对引物以及分别以不同荧光标记的TaqMan探针, 在同一个反应管中进行扩增。以相对定量指标△CT值区分唐氏综合征患者与正常人。采用EB 病毒转化技术, 把唐氏综合征患者外周血B 淋巴细胞转化成永生淋巴母细胞系作为标准品。通过优化反应条件, 使得目的基因和参照基因的扩增效率基本一致, 接近100%, 模板浓度在3～300 ng/μL范围内, △CT值的变异系数小于15%, 浓度在30 ng/μL时, 变异系数最小(＜10%), 以该浓度的DNA作为模板进行批内和批间实验的△CT值重复性好, 变异系数分别为9.8%和13.3%。运用建立的方法检测20例唐氏综合征患者的血标本和30例正常人的血标本, 正常人△CT值范围是-1.90～-1.30, 患者的△CT值范围是-2.95～-2.15, 两组之间无交叉重叠, 有明显差异(P＜0.001)。唐氏综合征患者永生细胞系建系成功 ,染色体核型和DNA 分析表明建系前后遗传是稳定的。因此, 实时荧光定量PCR比较△CT值的相对定量法快速诊断唐氏综合征是可行的。     

Protein levels of genes encoded on chromosome 21 in fetal Down syndrome brain: challenging the gene dosage effect hypothesis (Part III)

Summary.  Down syndrome (DS) is the most frequent genetic disorder with mental retardation and caused by trisomy 21. Although the gene dosage effect hypothesis has been proposed to explain the impact of extra chromosome 21 on the pathology of DS, a series of evidence that challenge this hypothesis has been reported. The availability of the complete sequences of genes on chromosome 21 serves now as starting point to find functional information of the gene products, but information on gene products is limited so far. We therefore evaluated expression levels of six proteins whose genes are encoded on chromosome 21 (synaptojanin-1, chromosome 21 open reading frame 2, oligomycin sensitivity confering protein, peptide 19, cystatin B and adenosine deaminase RNA-specific 2) in fetal cerebral cortex from DS and controls at 18–19 weeks of gestational age using Western blot analysis. Synaptojanin-1 and C21orf2 were increased in DS, but others were comparable between DS and controls, suggesting that the DS phenotype cannot be simply explained by gene dosage effects. We are systematically quantifying all proteins whose genes are encoded on chromosome 21 in order to provide a better understanding of the pathobiochemistry of DS at the protein level. These studies are of significance as they show for the first time protein levels that are carrying out specific function in human fetal brain with DS. Received August 12, 2002 Accepted September 12, 2002 Published online January 30, 2003 Authors' address: Prof. Dr. Gert Lubec, CChem, FRSC (UK) Department of Pediatrics, University of Vienna, Waehringer Guertel 18, A-1090 Vienna, Austria, Fax: +43-1-40400-3194, E-mail: gert.lubec@akh-wien.ac.at Abbreviations: ADAR2, adenosine deaminase RNA-specific 2; C21orf2, chromosome 21 open reading frame 2; DS, Down syndrome; NSE, neuron specific enolase; OSCP, oligomycin sensitivity conferring protein; PEP-19, peptide 19     

Far-Western based protein-protein interaction screening of high-density protein filter arrays

Even though a rough sketch of the human genome is now available and the number of newly discovered genes, which carry the potential of being biologically and medically relevant is currently greater than ever, only a small proportion has been assigned a biological function. Therefore, enormous attention is now increasingly being drawn towards functional genomics, i.e. the functional characterization of these newly identified sequences. In order to elucidate the role of a particular gene product within its cellular context, we have screened high-density protein filter arrays for protein-protein interactions on the basis of a 'Far-Western' based approach. The methodology described herein easily allows the identification and isolation of cDNAs of proteins, which interact with specific ligands (interacting proteins, antibodies and DNA/RNA sequences), and represents an alternative to tedious conventional protein interaction analyses. Far-Western screening in the context of a whole-genome expression analysis not only facilitates the assignment of biological functions to specific, newly identified protein and DNA sequences, but also is useful in studies that assess the binding capacity of mutant proteins to their interaction partner and in the identification of domains and amino acids involved in known protein-protein interactions. Taken together, we describe an approach that allows the easy and reproducible identification of protein ligands on the basis of a whole-genome expression analysis.     

Understanding mental retardation in Down's syndrome using trisomy 16 mouse models

Mental retardation in Down's syndrome, human trisomy 21, is characterized by developmental delays, language and memory deficits and other cognitive abnormalities. Neurophysiological and functional information is needed to understand the mechanisms of mental retardation in Down's syndrome. The trisomy mouse models provide windows into the molecular and developmental effects associated with abnormal chromosome numbers. The distal segment of mouse chromosome 16 is homologous to nearly the entire long arm of human chromosome 21. Therefore, mice with full or segmental trisomy 16 (Ts65Dn) are considered reliable animal models of Down's syndrome. Ts65Dn mice demonstrate impaired learning in spatial tests and abnormalities in hippocampal synaptic plasticity. We hypothesize that the physiological impairments in the Ts65Dn mouse hippocampus can model the suboptimal brain function occuring at various levels of Down's syndrome brain hierarchy, starting at a single neuron, and then affecting simple and complex neuronal networks. Once these elements create the gross brain structure, their dysfunctional activity cannot be overcome by extensive plasticity and redundancy, and therefore, at the end of the maturation period the mind inside this brain remains deficient and delayed in its capabilities. The complicated interactions that govern this aberrant developmental process cannot be rescued through existing compensatory mechanisms. In summary, overexpression of genes from chromosome 21 shifts biological homeostasis in the Down's syndrome brain to a new less functional state.     

Derangement of Hypothetical Proteins in Fetal Down's Syndrome Brain

The success of the Human Genome Project (HGP) enables prediction of proteins by computer programs from nucleic acid sequences and for which there is no experimental evidence. Clues for function of hypothetical proteins are provided by sequence similarity with proteins of known function in model organisms. The availability of this bulk of new data is of immediate importance to Down's syndrome (DS) research. DS is the most common human chromosomal abnormality caused by an extra copy of chromosome 21 and is characterized by somatic anomalies and mental retardation. In addition, overexpression of chromosome 21 genes is directly or indirectly responsible for mental retardation and other phenotypic abnormalities of DS. To allow insight into how trisomy 21 represents the phenotype of DS, we constructed a two-dimensional protein map and investigated expression of 8 hypothetical proteins in fetal DS (n = 7) and control (n = 7) brains (cortex). Two-dimensional electrophoresis (2-DE) with subsequent in-gel digestion of spots and matrix-assisted laser desorption/ionization (MALDI) spectroscopic identification followed by quantification of spots with specific software was applied. Quantitative analysis of hypothetical protein FLJ10849, hypothetical protein FLJ20113, and activator of hsp90 ATPase homologue 1 (AHA1) revealed levels comparable between DS and controls. By contrast, expression levels of hypothetical protein KIAA1185, hypothetical protein 55.2 kDa, hypothetical protein 58.8 kDa, actin-related protein 3beta (ARP3beta), and putative GTP-binding protein PTD004 were significantly decreased (P < 0.05) in fetal DS brain, and domain analysis suggests involvement in cytoskeleton, signaling, and chaperone system abnormalities.     

细胞信号转导与可变剪接调控

大多数真核基因能够发生可变剪接,其调控对于生理和病理状态下细胞功能的实现至关重要,而异常可变剪接则可导致多种疾病。虽然已知可变剪接能够在转录后水平调节基因表达,然而目前仍不清楚特定的可变剪接模式是如何被调控的。越来越多的研究发现细胞信号和外界环境刺激能够调控靶基因的剪接模式,并且已发现一些与可变剪接调控有关的信号转导通路,而后者能够通过修饰剪接因子进而改变剪接因子的亚细胞定位或者活性,从而实现对靶基因可变剪接模式的调控。由细胞信号转导通路所构成的网络能够灵活多样地调控基因剪接,一条信号通路可调控多个基因剪接,而多条信号通路也可调控同一基因剪接,对于理解信号转导过程的分子机制具有重要意义。     

The Alzheimer amyloid precursor-related transcript lacking the beta/A4 sequence is specifically increased in Alzheimer's disease brain

The deposition of cerebrovascular and plaque amyloid in the CNS is a primary feature of Alzheimer's disease and aged Down's syndrome pathology. The localization of the Alzheimer amyloid protein precursor (APP) gene on chromosome 21, along with its overexpression in Down's syndrome brain compared with normal brain, suggests that alterations in APP gene expression may play a role in the development of the neuropathology common to the two diseases. In the present report, we demonstrate that a specific spliced form of mRNA that is transcribed from the APP gene and that lacks the beta/A4 sequence is elevated in the nucleus basalis, occipitotemporal cortex, and parahippocampal gyrus in Alzheimer's disease brain relative to controls. These results are based on combined data from RNA slot blot analysis, in situ hybridization, and polymerase chain reaction quantification of specific mRNAs taken directly from tissue sections.     

Hits, Fhits and Nits: beyond enzymatic function

We have briefly summarized what is known about these proteins, but in closing wish to feature the outstanding questions. Hint1 was discovered mistakenly as an inhibitor of Protein Kinase C and designated Pkci, a designation that still confuses the literature. The other Hint family members were discovered by homology to Hint1. Aprataxin was discovered as a result of the hunt for a gene responsible for AOA1. Fhit was discovered through cloning of a familial chromosome translocation breakpoint on chromosome 3 that interrupts the large FHIT gene within an intron, in the FRA3B chromosome region (Ohta et al., 1996), now known to be the region of the human genome most susceptible to DNA damage due to replication stress (Durkin et al., 2008). The NitFhit fusion genewas discovered during searches for Fhit homologs in flies and worms because the fly/worm Nit polypeptide is fused to the 5'-end of the Fhit gene; the mammalian Nit gene family was discovered because of the NitFhit fusion gene, in searches for homologs to the Nit polypeptide of the NitFhit gene. Each of the Hit family member proteins is reported to have enzymatic activities toward putative substrates involving nucleosides or dinucleosides. Most surprisingly, each of the Hit family proteins discussed has been implicated in important DNA damage response pathways and/or tumor suppression pathways. And for each of them it has been difficult to assign definite substrates, to know if the substrates and catalytic products have biological functions, to know if that function is related to the DNA damage response and suppressor functions, and to precisely define the pathways through which tumor suppression occurs. When the fly Nit sequence was found at the 5'-end of the fly Fhit gene, this gene was hailed as a Rosetta stone gene/protein that would help in discovery of the function of Fhit, because the Nit protein should be in the same signal pathway (Pace et al., 2000). However, the mammalian Nit family proteins have turned out to be at least as mysterious as the Fhit proteins, with the Nit1 substrate still unknown and the surprising finding that Nit proteins also appear to behave as tumor suppressor proteins. Whether the predicted enzymatic functions of these proteins are relevant to the observed biological functions, remain among the outstanding unanswered puzzles and raise the question: have these mammalian proteins evolved beyond the putative original enzymatic purpose, such that the catalytic function is now vestigial and subservient to signal pathways that use the protein-substrate complexes in pathways that signal apoptosis or DNA damage response? Or can these proteins be fulfilling catalytic functions independently but in parallel with signal pathway functions, as perhaps observed for Aprataxin? Or is the catalytic function indeed part of the observed biological functions, such as apoptosis and tumor suppression? Perhaps the recent, post-genomic focus on metabolomics and genome-wide investigations of signal pathway networks will lead to answers to some of these outstanding questions.     

Analyzing the pathways enriched in genes associated with nicotine dependence in the context of human protein–protein interaction network

Nicotine dependence is the primary addictive stage of cigarette smoking. Although a lot of studies have been performed to explore the molecular mechanism underlying nicotine dependence, our understanding on this disorder is still far from complete. Over the past decades, an increasing number of candidate genes involved in nicotine dependence have been identified by different technical approaches, including the genetic association analysis. In this study, we performed a comprehensive collection of candidate genes reported to be genetically associated with nicotine dependence. Then, the biochemical pathways enriched in these genes were identified by considering the gene’s propensity to be related to nicotine dependence. One of the most widely used pathway enrichment analysis approach, over-representation analysis, ignores the function non-equivalence of genes in candidate gene set and may have low discriminative power in identifying some dysfunctional pathways. To overcome such drawbacks, we constructed a comprehensive human protein–protein interaction network, and then assigned a function weighting score to each candidate gene based on their network topological features. Evaluation indicated the function weighting score scheme was consistent with available evidence. Finally, the function weighting scores of the candidate genes were incorporated into pathway analysis to identify the dysfunctional pathways involved in nicotine dependence, and the interactions between pathways was detected by pathway crosstalk analysis. Compared to conventional over-representation-based pathway analysis tool, the modified method exhibited improved discriminative power and detected some novel pathways potentially underlying nicotine dependence. In summary, we conducted a comprehensive collection of genes associated with nicotine dependence and then detected the biochemical pathways enriched in these genes using a modified pathway enrichment analysis approach with function weighting score of candidate genes integrated. Our results may provide insight into the molecular mechanism underlying nicotine dependence.     

A genomewide suppressor and enhancer analysis of cdc13-1 reveals varied cellular processes influencing telomere capping in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, Cdc13 binds telomeric DNA to recruit telomerase and to "cap" chromosome ends. In temperature-sensitive cdc13-1 mutants telomeric DNA is degraded and cell-cycle progression is inhibited. To identify novel proteins and pathways that cap telomeres, or that respond to uncapped telomeres, we combined cdc13-1 with the yeast gene deletion collection and used high-throughput spot-test assays to measure growth. We identified 369 gene deletions, in eight different phenotypic classes, that reproducibly demonstrated subtle genetic interactions with the cdc13-1 mutation. As expected, we identified DNA damage checkpoint, nonsense-mediated decay and telomerase components in our screen. However, we also identified genes affecting casein kinase II activity, cell polarity, mRNA degradation, mitochondrial function, phosphate transport, iron transport, protein degradation, and other functions. We also identified a number of genes of previously unknown function that we term RTC, for restriction of telomere capping, or MTC, for maintenance of telomere capping. It seems likely that many of the newly identified pathways/processes that affect growth of budding yeast cdc13-1 mutants will play evolutionarily conserved roles at telomeres. The high-throughput spot-testing approach that we describe is generally applicable and could aid in understanding other aspects of eukaryotic cell biology.