A carbon allotrope based on "sp" hybridization containing alternating triple and single bonds (an acetylenic or linear carbon allotrope) has been prepared. Studies of small (8 to 28 carbon atoms) acetylenic carbon model compounds show that such species are quite stable (130 degrees to 140 degrees C) provided that nonreactive terminal groups or end caps (such as tert-butyl or trifluoromethyl) are present to stabilize these molecules against further reactions. In the presence of end capping groups, laser-based synthetic techniques similar to those normally used to generate fullerenes, produce thermally stable acetylenic carbon species capped with trifluoromethyl or nitrile groups with chain lengths in excess of 300 carbon atoms. Under these conditions, only a negligible quantity of fullerenes is produced. Acetylenic carbon compounds are not particularly moisture or oxygen sensitive but are moderately light sensitive.
In Saccharomyces cerevisiae, the three-carbon of serine is normally the major one-carbon donor, although glycine and formate can substitute for serine. The second carbon of glycine enters via the glycine cleavage system in the mitochondria and can satisfy all cellular one-carbon requirements. It remains unresolved, however, as to the route by which these mitochondrial one-carbon units supply cytosolic anabolic processes. In the present work, we have used yeast mutants blocked at selected sites and 13C NMR to trace the incorporation of glycine-derived mitochondrial 5,10-methylenetetrahydrofolate into nonmitochondrial synthesis of choline and purines. Label incorporation into choline traces the methylation pathway of choline synthesis from production of serine to methylation of phosphatidylethanolamine. The active one-carbon unit of S-adenosylmethionine involved in methylation reactions originates almost solely from C3 of serine. On the other hand, flow of mitochondrial one-carbon units to 10-formyltetrahydrofolate for purine synthesis is shown to occur via both serine and formate. Formate transport accounts for at least 25% of the total, even during growth with sufficient serine to provide for the one-carbon requirements of the cell. This work shows that the synthetase function of the cytosolic C1-tetrahydrofolate synthase plays a critical role in the processing of mitochondrial one-carbon units to 10-formyltetrahydrofolate pools. In addition, this study provides evidence of two pools of glycine within the mitochondria and establishes a system of analyzing flux into the different folate derivatives.
Gas-phase hydrogen/deuterium exchange reactions have
been performed on the 5‘- and 3‘-nucleotide monophosphates and on the 3‘,5‘-cyclic nucleotides. Following
negative mode electrospray ionization and transport to a
Fourier transform ion cyclotron resonance cell, each
nucleotide was reacted with gaseous D2O for up to 600
s. Extensive deuterium exchange was observed for the
3‘- and 5‘-nucleotides in negative ion mass spectra with
relative rates of exchange following the trend 5‘-dCMP >
5‘-dAMP > 5‘-dTMP ≫ 5‘-dGMP and 3‘-dGMP >3‘-dAMP
≈ 3‘-dCMP ≈ 3‘-dTMP. At least two classes of exchanging
protons are observed. The more facile class is assigned
to the amino protons of the bases, with a slower class
attributed to the phosphate and/or hydroxyl proton.
Overall, the 3‘-nucleotides exchange more quickly than
the 5‘-oligonucleotides. The cyclic nucleotides did not
undergo deuterium exchange, suggesting that a charged
phosphate group proximate to the base is required to
catalyze the exchange reaction. Exchange through tautomerization of the bases is not observed, although
molecular modeling suggests an energy barrier of <30
kcal.
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