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Telomere

Historically, 5. japonicum has been considered to be a genetically diverse parasite with different geographic isolates showing variation in snail host specificity (Chiu, 1967), pathogenicity and development (Hsu and Hsu, 1962), morphology (Sobhon et al., 1986) and [Pg.54]

It has been noticed that somatal cell lines cultured in vitro reproduce about 20 to 50 times and then the cells die. This has prompted biologists to specnlate that there is a natural end to multicellular BU in vivo. One reason for this may be events in the process of cellular mitosis, as chromosomes are split and replicated. Replication requires an involved series of steps, and includes RNA priming, DNA primase, DNA polymerase, and DNA ligase in an intricate set of maneuvers. These steps, however, are not able to replicate the end of the DNA strand. Errors in the replication process can [Pg.383]

There is an enzyme called telomerase that functions by restoring the length of the telomeres. It is present in germ line cells, which enables a new individual to begin life with a full potential life span. [Pg.384]

FIGURE6.18.1 Telomeres are bits of genetic material whose function is to guard against errors in useful genes. [Pg.384]


Ziegler process) and telomerization of alkenes to medium chain derivatives for detergents and fats. Both processes operate by insertion of an alkene into AIR bonds. [Pg.26]

CH2 CH C CH. Colourless gas with a sweet odour b.p. 5°C. Manufactured by the controlled low-temperature telomerization of ethyne in the presence of an aqueous solution of CuCI and NH Cl. Reduced by hydrogen to butadiene and, finally, butane. Reacts with water in the presence of HgSO to give methyl vinyl ketone. Forms salts. Forms 2-chloro-butadiene (chloroprene) with hydrochloric acid and certain metallic chlorides. [Pg.266]

Dimerization and Telomerization of Conjugated Dienes and Related Reactions... [Pg.423]

The dimerization of isoprene is possible, but the reaction of isoprene is slower than that of butadiene. Dimerization or telomerization of isoprene, if carried out regioselectively to give a tail-to-liead dimer 18 or a head-to-tail... [Pg.425]

Although acetonitrile is one of the more stable nitriles, it undergoes typical nitrile reactions and is used to produce many types of nitrogen-containing compounds, eg, amides (15), amines (16,17) higher molecular weight mono- and dinitriles (18,19) halogenated nitriles (20) ketones (21) isocyanates (22) heterocycles, eg, pyridines (23), and imidazolines (24). It can be trimerized to. f-trimethyltriazine (25) and has been telomerized with ethylene (26) and copolymerized with a-epoxides (27). [Pg.219]

The higher molecular weight petfluoroalkyl iodides ate prepared by telomerization of tetrafluoroethylene with lower molecular weight perfluoroalkyl iodides (46,48). [Pg.290]

Prepa.ra.tlon There are five methods for the preparation of long-chain perfluorinated carboxyUc acids and derivatives electrochemical fluorination, direct fluorination, telomerization of tetrafluoroethylene, oligomerization of hexafluoropropylene oxide, and photooxidation of tetrafluoroethylene and hexafluoropropylene. [Pg.310]

Fluorinated carboxyflc acids are also prepared by telomerization of tetrafluoroethylene, followed by oxidation (19—21). [Pg.310]

The lower molecular weight oils, waxes, and greases of PCTFE can be prepared direcdy by telomerization of the monomer or by pyrolysis of the higher molecular weight polymer (45—54). [Pg.394]

Other common radical-initiated polymer processes include curing of resins, eg, unsaturated polyester—styrene blends curing of mbber grafting of vinyl monomers onto polymer backbones and telomerizations. [Pg.220]

A telomerization reaction of isoprene can be carried out by treatment with 2-chloro-3-pentene, prepared by the addition of dry HCl to 1,3-pentadiene (67). An equimolar amount of isoprene in dichi oromethane reacts with the 2-chloro-3-pentene at 10°C with stannic chloride as catalyst. l-Chloro-3,5-dimethyl-2,6-octadiene is obtained in 80% yield by 1,4-addition. [Pg.465]

Telomerization. Polymerization of DAP is accelerated by telogens such as CBr, which are more effective chain-transfer agents than the monomer itself (65) gelation is delayed. The telomers are more readily cured in uv than DAP prepolymers. In telomerizations with CCl with peroxide initiator, at a DAP/CCl ratio of 20, the polymer recovered at low conversion has a DP of 12 (66). [Pg.85]

Isoprene (2-methyl-1,3-butadiene) can be telomerized in diethylamine with / -butyUithium as the catalyst to a mixture of A/,N-diethylneryl- and geranylamines. Oxidation of the amines with hydrogen peroxide gives the amine oxides, which, by the Meisenheimer rearrangement and subsequent pyrolysis, produce linalool in an overall yield of about 70% (127—129). [Pg.420]

Synthetic methods for the production of citroneUal iaclude the catalytic dehydrogenation of citroneUol (110), the telomerization of isoprene (151), and the Utbium-catalyzed reaction of myrcene with secondary alkylamines (128). [Pg.425]

Telomerization Reactions. Butadiene can react readily with a number of chain-transfer agents to undergo telomerization reactions. The more often studied reagents are carbon dioxide (167—178), water (179—181), ammonia (182), alcohols (183—185), amines (186), acetic acid (187), water and CO2 (188), ammonia and CO2 (189), epoxide and CO2 (190), mercaptans (191), and other systems (171). These reactions have been widely studied and used in making unsaturated lactones, alcohols, amines, ethers, esters, and many other compounds. [Pg.345]

Coupling of butadiene with CO2 under electrochemically reducing conditions produces decadienedioic acid, and pentenoic acid, as weU as hexenedioic acid (192). A review article on diene telomerization reactions catalyzed by transition metal catalysts has been pubUshed (193). [Pg.345]

Carbon tetrachloride forms telomers with ethylene and certain other olefins (14—16). The mixture of Hquid products derived from ethylene telomerization may be represented CCl2(CH2CH2) Cl ia which nis 2l small number. Reaction of ethylene and carbon tetrachloride takes place under pressure and is induced by the presence of a peroxygen compound, eg, ben2oyl peroxide (17—19) or metal carbonyls (14,15). [Pg.531]

Telomerization of 3,3-dimethyldiaziridine with butadiene catalyzed by Pd complexes yielded 2 1 adducts (123) and (124) (80IZV220). [Pg.213]

Homolytic cleavage of dlazonlum salts to produce aryl radicals is induced by titan1um(III) salt, which is also effective in reducing the a-carbonylalkyl radical adduct to olefins, telotnerization of methyl vinyl ketone, and dimerization of the adduct radicals. The reaction can be used with other electron-deficient olefins, but telomerization or dimerization are important side reactions. [Pg.70]

Chloro-2,2,3-trifluoropropionic acid has been prepared by permanganate oxidation of 3-chloro-2,2,3-trifluoropropanol which is one of the telomerization products of chlorotrifluoroethylene with methanol. The present procedure is a modification of one reported earlier and is undoubtedly the method of choice for making propionic acids containing 2 fluorine atoms, i.e., 2,2,3,3-tetrafluoropropionic acid, 3,3-dichloro-2,2-difluoropropionic acid, and 3-bromo-2,2,3-trifluoropropionic acid. When preparing 2,2,3,3-tetrafluoropropionic acid from tetrafluoroethylene, it is desirable to use an additional 50 ml. of acetonitrile and externally applied heat to initiate the reaction. [Pg.13]

Similarly, Itexafluoroprapylene undergoes fluoride ion induced homotelo-merization to give a series of dimers and trimers These telomerizations can be induced by other nucleophiles, such as amines Indeed, the selectivity of the pi oce-,s can be changed significantly by varying reagents and reaction conditions [25, 26] (equations 19 and 20)... [Pg.750]

ITowever, most normal somatic cells lack telomerase. Consequently, upon every cycle of cell division when the cell replicates its DNA, about 50-nucleotide portions are lost from the end of each telomere. Thus, over time, the telomeres of somatic cells in animals become shorter and shorter, eventually leading to chromosome instability and cell death. This phenomenon has led some scientists to espouse a telomere theory of aging that implicates telomere shortening as the principal factor in cell, tissue, and even organism aging. Interestingly, cancer cells appear immortal because they continue to reproduce indefinitely. A survey of 20 different tumor types by Geron Corporation of Menlo Park, California, revealed that all contained telomerase activity. [Pg.382]

The palladium-catalyzed hnear telomerization of 1,3-bntklienes provides a useful method for thepreparation of functionalized alkenes. A proposed catalytic cycle for the paliadinm-catalyzed... [Pg.138]

Temperature-dependent phase behavior was first applied to separate products from an ionic liquid/catalyst solution by de Souza and Dupont in the telomerization of butadiene and water [34]. This concept is especially attractive if one of the substrates shows limited solubility in the ionic liquid solvent. [Pg.232]

In addition to the applications reported in detail above, a number of other transition metal-catalyzed reactions in ionic liquids have been carried out with some success in recent years, illustrating the broad versatility of the methodology. Butadiene telomerization [34], olefin metathesis [110], carbonylation [111], allylic alkylation [112] and substitution [113], and Trost-Tsuji-coupling [114] are other examples of high value for synthetic chemists. [Pg.252]

When the products are partially or totally miscible in the ionic phase, separation is much more complicated (Table 5.3-2, cases c-e). One advantageous option can be to perform the reaction in one single phase, thus avoiding diffusional limitation, and to separate the products in a further step by extraction. Such technology has already been demonstrated for aqueous biphasic systems. This is the case for the palladium-catalyzed telomerization of butadiene with water, developed by Kuraray, which uses a sulfolane/water mixture as the solvent [17]. The products are soluble in water, which is also the nucleophile. The high-boiling by-products are extracted with a solvent (such as hexane) that is immiscible in the polar phase. This method... [Pg.264]


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2,3-dimethyl butadiene, telomerization

A telomerization

Acetic acid telomerization, with butadiene

Acrylate telomerization

Alcohols telomerization with butadiene

Alcohols telomerization with isoprene

Alkenes telomerization

Allyl acetate, telomerization

Amines telomeric

Amines telomerization

Aromatic hydrocarbons, telomerization

Butadiene telomerization technique

Butadiene telomerization with nitroalkane

Butadiene, catalyzed reactions telomerization

Carbon dioxide telomerization

Ciliate telomeres

Condensation telomerization

Conjugated dienes telomerization

Copolymers Telomerization

Deregulation of Telomere-Binding Proteins

Dienes telomerization

Dienes/alcohols, telomerization

Diolefins, telomerization

Enamines, telomerization with butadiene

Ethylene glycol, telomerization

Ethylene telomerization

Four-Repeat Human Telomeric Sequence

Free radical polymerization telomerization

Human telomere sequence

Hydrogen chloride, telomerization

Importance of Telomere Ends and Replication Processes

Intramolecular telomerization

Isoprene telomerization

Isoprene telomerization with amine

Ligands telomerizations

Macromonomers telomerization

Metathesis telomerization

Nickel-complex-catalyzed reactions telomerization

Nitroalkane, telomerization with

Palladium complex catalysis telomerization

Palladium telomerization

Palladium-catalysed reactions telomerization

Phenol, telomerization with butadiene

Phenols, telomerization

Polymerization telomerization

Polyols telomerization

Polysaccharides, telomerization

Prevention telomerization

Reaction telomerization

Resistance and Telomere Component Expression

Starch telomerization

Sucrose telomerization with butadiene

Sucrose, telomerization

Telechelic Oligomers Obtained by Telomerization

Telechelic telomerization

Telomere binding proteins

Telomere capping

Telomere elongation

Telomere ends

Telomere length

Telomere shortening

Telomeres and Apoptosis

Telomeres and telomerase in tumour cells

Telomeres maintenance

Telomeres synthesis, figure

Telomeres, replication

Telomeric DNA

Telomeric End-Binding Proteins

Telomeric repeat amplification protocol

Telomeric repeat amplification protocol assay

Telomeric repeats

Telomeric sequences

Telomerization

Telomerization

Telomerization Subject

Telomerization additive

Telomerization butadiene

Telomerization butadiene/ethylene glycol

Telomerization catalysts

Telomerization glycol

Telomerization mechanism

Telomerization of 1,3-Butadiene the Kuraray Process

Telomerization of 2,3-Dimethylbutadiene

Telomerization of Butadiene with Alcohols and Phenol

Telomerization of Butadiene with C—H-Acidic Compounds

Telomerization of Butadiene with Nitroalkanes

Telomerization of Piperylene

Telomerization of butadiene

Telomerization of butadiene with

Telomerization of butadiene with ammonia

Telomerization of butadiene with sucrose

Telomerization of diene

Telomerization of dienes

Telomerization of ethylene and

Telomerization of isoprene

Telomerization products

Telomerization reaction amines

Telomerization studies

Telomerization telechelic oligomers

Telomerization telogens

Telomerization telomer

Telomerization terminator

Telomerization to yield amines

Telomerization with olefins

Telomerization, butadiene/carbon dioxid

Telomerization, inhibition

Telomerization, of ethylene

Telomerization, telechelic oligomer

Telomerizations

Telomerizations and Oligomerizations

Telomerizations of olefines

Tetrafluoroethylene telomerization

Vinylidene fluoride telomerization

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