ABSTRACT
OBJECTIVE: To explore the effect of occupational lead exposure on the relative telomere length(RTL) and mRNA expression of telomere-binding protein POT1-interacting protein 1(TPP1) in peripheral blood of workers. METHODS: A total of 303 workers exposed to lead were selected as the exposure group and 72 administrative logisticians personnel in the same factory as the control group using the simple random sampling method. Their peripheral blood samples were collected and were used to detect the blood lead level by Graphite furnace atomic absorption spectrometry. RTL and the relative expression of TPP1 mRNA by real-time quantitative polymerase chain reaction. RESULTS: The blood lead level of the exposure group was higher [Media(M): 68.2 vs 266.1 μg/L, P<0.01], the RTL was shorter(M: 0.96 vs 0.70, P<0.01), and the relative mRNA expression of TPP1 was lower(M: 0.92 vs 0.51, P<0.01) compared with the control group. Spearman correlation analysis results showed that the blood lead level were both negatively correlated with RTL [Spearman correlation coefficient(r_S) =-0.18, P<0.01], and the relative mRNA expression of TPP1(r_S=-0.19, P<0.01), while the RTL was positively correlated with the risk of RTL shortening and the relative mRNA expression of TPP1 decline was increased in lead exposure(P<0.01). CONCLUSION: Lead exposure can shorten the RTL and reduce the relative mRNA expression of TPP1 in workers. The mechanism may be that lead interferes with telomere repair process by inhibiting the mRNA expression of TPP1.
ABSTRACT
Background: TRF2 (telomeric repeat binding factor 2) is an essential component of the telomere-binding protein complex shelterin. TRF2 induces the formation of a special structure of telomeric DNA and counteracts activation of DNA damage-response pathways telomeres. TRF2 has a poorly characterized linker region (udTRF2) between its homodimerization and DNA-binding domains. Some lines of evidence have shown that this region could be involved in TRF2 interaction with nuclear lamina. Results: In this study, the fragment of the TERF2 gene encoding udTRF2 domain of telomere-binding protein TRF2 was produced by PCR and cloned into the pET32a vector. The resulting plasmid pET32a-udTRF2 was used for the expression of the recombinant udTRF2 in E. coli RosettaBlue (DE3). The protein was isolated and purified using ammonium sulfate precipitation followed by ion-exchange chromatography. The purified recombinant protein udTRF2 was injected into guinea pigs to generate polyclonal antibodies. The ability of anti-udTRF2 antibodies to bind endogenous TRF2 in human skin fibroblasts was tested by western blotting and immunofluorescent staining. Conclusions: In this study, the recombinant protein udTRF2 and antibodies to it were generated. Both protein and antibodies will provide a useful tool for investigation of the functions of the udTRF2 domain and its role in the interaction between TRF2 and nuclear lamina.
Subject(s)
Animals , Guinea Pigs , Telomeric Repeat Binding Protein 2/metabolism , Antibodies/metabolism , Plasmids , Recombinant Proteins/metabolism , Immunohistochemistry , Blotting, Western , Chromosomes , Cloning, Molecular , Nuclear Lamina , Telomeric Repeat Binding Protein 2/genetics , Immunoprecipitation , DNA-Binding Proteins/metabolism , Escherichia coli/metabolism , Antibodies/isolation & purification , Antibody Formation , NucleoproteinsABSTRACT
Los telómeros son estructuras complejas de ADN y proteína localizadas en el extremo de los cromosomas eucariotes. Su principal función es proteger el extremo cromosomal de ser reconocido y procesado como ADNs fracturado, evitando así eventos de recombinación y fusión que conducen a inestabilidad cromosomal. El ADN telomérico consta de secuencias cortas, repetidas una tras otra, ricas en guanina; la cadena rica en guanina se extiende formando una región de cadena sencilla denominada extremo 3' protuberante. Las proteínas por su parte, se pueden clasificar en: dsBPs, o proteínas de unión a la cadena doble, GBPs aquellas que reconocen específicamente el extremo protuberante y, proteínas que las interconectan mediante interacciones proteína-proteína. El gen PF3D7_1006800 de Plasmodium falciparum codifica para una proteína putativa similar a una GBP de Criptosporidium parvum, con el fin de establecer si esta proteína de P. falciparum presenta la capacidad de unión al ADN telomérico del parásito, se produjo una proteína recombinante a partir de la región codificante del gen, se purificó y se utilizó en ensayos de unión a ADN, y en la generación de anticuerpos policlonales específicos contra PfGBP. Nuestros resultados indican que la proteína de P. falciparum es una proteína nuclear con capacidad de unión al ADN telomérico in vitro, por lo que podría ser parte del complejo proteico encargado de proteger y/o mantener el telómero in vivo.
Telomeres are specialized structures at the end of chromosomes that consist of repetitive DNA sequences and associated proteins. The primary role of telomeres is to protect the end of linear chromosomes from recombination, fusion, and recognition as broken DNA ends. This protective function can be achieved through association with specific telomere binding proteins. Telomeric DNA consists of G-rich double-stranded arrays followed by a single-stranded G-rich overhang. The telomeric proteins can be classified in dsBPs, which bind double-stranded DNA, GBPs those that bind specifically to G-rich overhang, and proteins that interact with telomeric factors. Plasmodium falciparum gene PF3D7_1006800 codifies for a protein highly similar to Cryptosporidium parvum GBP. In order to investigate whether the P. falciparum protein binds telomeric DNA, a recombinant protein was produced, purified and DNA binding assays were performed. Polyclonal antibodies against rPfGBP were produced and tested in western blot. Our results indicate that PfGBP is a nuclear protein that binds telomeric DNA in vitro, which could be part of the protein complex responsible for protecting and/or maintaining the telomere in vivo.
Os telómeros são estruturas complexas de DNA e proteína localizadas no extremo dos cromossomas dos eucariotas. Sua principal função é proteger o extremo dos cromossomas para que não sejam reconhecidos e processados como DNAs fraturados. O anterior evita eventos de recombinação e fusão que conduzem à instabilidade nos cromossomas. O DNA telomérico tem sequencias curtas e repetidas, ricas em guanina. A cadeia rica em guanina estende-se para formar uma região de cadeia simples chamada extremo 3' protuberante. As proteínas podem-se classificar em: dsBPs ou proteínas de união à cadeia dupla, GBPs que são as que reconhecem especificamente o extremo protuberante e, as proteínas que interligam mediante interações proteína-proteína. O gene PF3D7_1006800 de Plasmodium falciparum codifica para uma proteína similar a uma GBP de Criptosporidium parvum. Com o objetivo de estabelecer se a proteína de P. falciparum presenta a capacidade de união ao DNA telomérico, foi produzida uma proteína recombinante partindo da região codificante do gene, purificou-se e utilizou-se nos ensaios de união ao DNA e na geração de anticorpos policlonais específicos contra PfGBP. Os nossos resultados indicam que a proteína de P. falciparum é uma proteína nuclear com capacidade de união ao DNA telomérico in vitro, pelo que poderia fazer parte do complexo proteico encarregado de proteger e/ou manter o telómero in vivo.
ABSTRACT
Aims: Human telomere repeat binding factor (hTRF2) is a double stranded telomere binding protein that plays key role in protecting the chromosome ends and a necessary building block of telomere structure maintenance. The aim of the present study was to focus on the modeling of 3D structure of hTRF2 (500 residues long) and its interaction studies with DNA in silico. Study Design: The overall work was designed in different steps starting with the modeling of the concerned protein, its physiochemical properties study, modeling of 3DDNA with specific length and varying bend angle, docking studies of modeled DNA and hTRF2 protein. Place and Duration of Study: Bioinformatics Lab, Department of Biotechnology, Birla Institute of Technology, Mesra, India. November 2012- July 2013. Methodology: 3D structure of hTRF2 was modeled through I-TASSER method. The modeled structure was verified by 5ns of simulation run in solvent (water) condition and also evaluated with different bioinformatics tools. Physiochemical properties were calculated through CLC Protein Workbench. DNA 3D structure was modeled with the conserved nucleotide sequence motif, TTAGGG with varying bend angles of 0° to 60°. The DNA-protein docking studies were carried out through HADDOCK easy interface for each bend angle. Results: The best model was selected depending on minimum RMSD value and C-Score and the Stereochemical quality of that model was verified with different tools, as the Molprobity score (>1) of hTRF2 was predicted 4.2 and Ramachandra favored residue was 80.56%. The selected model protein and DNA structure was docked and among all the docking results the best orientation of DNA and hTRF2 was at 60° DNA bend angle with lowest RMSD and maximum Z-value. The amino acids which are directly involved in the interaction were also selected. Conclusion: In future further study will be planned with further bend angle for getting better information on DNA-protein interactions. In silico studies will also be helpful for the researchers to study the complex structure in vitro.
ABSTRACT
BACKGROUND: Telomere-associated proteins wil directly affect the function of telomeres, adjust the length of telomeric DNA, which are closely related with cellsenescence and carcinogenesis. OBJECTIVE: To find the key regulatory molecules in the cellsenescence process through observing the telomere-associated factor expression in normal cel replicative senescence process. METHODS: Based on established cel replicative senescence model, reverse transcription-PCR and western blot were used to detect the telomere-associated factor expression on the molecular and protein levels, including the telomere-associated factor human telomere binding protein 1, tankyrase 1, telomerase RNA, telomere protection protein 1 and P53 expressions in the human embryonic lung fibroblast replicative senescence. RESULTS AND CONCLUSION: The results showed that with the cellsenescence, transcription of human telomere binding protein 1 did not changed, while the protein expression of human telomere binding protein 1 was increased gradual y and then decreased rapidly; mRNA and protein expressions of telomere protection protein 1 did not changed; with the human embryonic lung fibroblast replicative senescence, expression of telomere protection protein 1 was decreased gradual y; with cellsenescence, telomerase RNA component showed an increasing trend; protein expression of P53 did not changed. Human telomere binding protein 1, telomere protection protein 1 and telomerase RNA play an important role in cellsenescence.
ABSTRACT
Gradual attrition of telomere to a critical short length elicits successive cellular response of cellular senescence and crisis. Cancer cells evade this process by maintaining functional telomeres via one of two known mechanisms of telomere maintenance. The first and most frequent mechanism involves reactivation of enzyme activity of telomerase, a ribonucleoprotein complex mainly via transcriptional up-regulation of TERT, a catalytic subunit of telomerase complex. The second mechanism utilizes telomerase-independent way termed ALT (for Alternative Lengthening of Telomere), which possibly involves recombination pathways. Thus master key for cellular immortalization is supposed to possess adequate telomere reserves. Indeed, telomerase can alone induce the immortalization under culture on feeder cell layers without generally known inactivation mechanism of tumor suppressor genes. Including this phenomena, this review will focus on telomerase and telomere-associated proteins, thereby implication of these proteins for cellular immortalization processes.