Methylated Polyl(L-lysine): Conformational Effects and Interactions with Polynucleotides

Bello, Jake; Granados, Edward N.; Lewinski, Steven; Bello, Helene R.; Trueheart, Thomas

doi:10.1080/07391102.1985.10507608

Cited by 5 publications

(1 citation statement)

References 32 publications

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“…Lysine methylation has also been shown to alter the conformation of a target polypeptide. 26 Alternatively, the altered conformation might favor the binding of E3 ligases or proteins involved in the degradation of the substrate [Fig. 2B, (2)].…”

Section: Functions Of Set9-mediated Lysine Methylationmentioning

confidence: 99%

Methylation, a new epigenetic mark for protein stability

Yang¹,

Lamb²,

Chen³

2009

Epigenetics

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Recent studies on the lysine methylation of histones have moved rapidly thanks to the discoveries of a variety of histone lysine methyltransferases. Histone lysine methylation is known to either activate or repress gene expression depending upon the position and status of the methylated lysine residue. Recently, an increasing number of lysine methyltransferases have been identified to modify non-histone proteins. Among those enzymes, the most extensively studied is Set9, a SET domain-containing lysine methyltransferase. Set9 was initially found to target histone H3 lysine 4 for monomethylation and was subsequently shown to target a variety of non-histone proteins, especially transcription-related factors. Functional studies revealed that Set9-mediated methylation of different non-histone proteins leads to distinct biological consequences, most of which point to protein stability. Here we summarize the latest findings on the effects of Set9-mediated lysine methylation on the stability of non-histone proteins.

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Section: Functions Of Set9-mediated Lysine Methylationmentioning

confidence: 99%

Methylation, a new epigenetic mark for protein stability

Yang¹,

Lamb²,

Chen³

2009

Epigenetics

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Formation and stability of helical poly (N^ϵ, N^ϵ, N^ϵ‐trimethyl‐L‐lysine) in sodium perchlorate solution

Bello

1988

Biopolymers

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SynopsisPoly(trimethy1-L-lysine), [Lys(Mq)],, is converted from random coil to a-helix at about 1/30 of the NaC10, concentration required by poly(L-lysine), (Lys),. NaClO, generates turbidity in [Lys (Me),], at concentrations above that required for helix formation, and decreases turbidity above 1M NaC10,. The turbidity runs parallel to enhanced, and then decreased, fluorescence of a dansyl label. Helix formation per se does not induce enhanced fluorescence. Increasing NaC10, concentration increases T, linearly with log[NaClO,] for both (Lys), and [Lys(Mq], until the denaturing effect of high NaC10, sets in. Increasing NaClO, also increases the breadth of the transition. Heating helical [Lys(Mq)], or (Lys), does not produce a CD spectrum resembling that of "random-coil" (Lys),, except for [Lys(Mq)], at relatively low NaC10, concentration. INTRODUCTIONAn interesting fact about poly(L-lysine), (Lys),, is that perchlorates convert it from the random coil to the a-heli~.'-~ At 0.3M NaClO,, (Lys), is about 50% helical at room temperature.' Thiocyanate also promotes a-helix fonnat i~n ,~ as does trichloracetate.6 Many other anions, notably chloride, have no such effect. Poly(L-arginine) is converted to the a-helix, with 50% helicity a t about 0.05M NaC10, at room temperature: or 1/6 of that required for (Lys),. Poly(L-arginine) is also converted to the a-helix by sulfate, carbonate, and phosphate.8 Poly(L-ornithine) forms a-helix in ClO; as well but only to about 50% .9-11 Perchlorate also induces a-helix in poly(S-methylsulfonium-L-methionine), with a significant amount of helix formed at 25°C with ClO, present only as the stoichiometric counterion.12 It was reported from this laboratory earlier1'J3 that random-coil poly(N',N',N'-trimethyl-L-lysine), [Lys(Me,)],, is also converted to an ordered form, probably an a-helix, by 0.5-1M NaC10,. The interpretation of the CD spectrum, however, was not clear, as it appeared that the spectrum was distorted by the effect of turbidity. The present report describes further work on the effect of ClO, on the formation and stability of the helix in (Lys), and [Lys(Me,)],. MATERIALS AND METHODS(Lys * HBr), was obtained from Sigma. The absorption spectnln of this lot of (Lys), showed residual carbobenzyloxy blocking groups to be below 4 per 1000 lysine residues. The CD spectrum in the absence of NaC10, is in agreement with that reported by Rao and Miller', for (Lys), essentially free The reaction mixture was dialyzed in the cold against water, then against approximately 0.05M NaClO,, which caused precipitation, then against water (resulting in redissolution). Dansylated (Lys), was also put through a mock reaction without dimethyl sulfate and was dialyzed the same way, but no precipitation occurred. Both polypeptides were freeze dried. CD spectra were obtained with a Jasco 500A. Temperatures were measured with a platinum resistance element and a digital temperature indicator (Omega Model 199P2), and were constant to 0.2"C a t the highest temperature. Temperature was controlled by a circ...

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Helix formation in methylated copolymers of lysine and alanine

Bello

1992

Biopolymers

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Random copolymers of lysine and alanine, 2:1 and 1:1, were trimethylated on the lysine amino groups to quaternary ammonium groups. Methylated and unmethylated polymers were prepared with Cl- or ClO4- as the counterion. CD spectra were measured for increasing concentration of peptide without added salt, and at constant peptide concentration in increasing NaCl or NaClO4. Unmethylated peptides, as the chloride, form alpha-helix more readily than do the methylated peptides. The opposite occurs with ClO4- as counterion. The helix-promoting effect of methylated lysine residues (ClO4- counterion) is diminished by the presence of alanine, as compared with effects when lysine is the only type of residue. The effect of methylation of proteins on helix formation may depend on the types of anionic groups with which the protein may be involved.

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Methylated Polyl(L-lysine): Conformational Effects and Interactions with Polynucleotides

Cited by 5 publications

References 32 publications

Methylation, a new epigenetic mark for protein stability

Methylation, a new epigenetic mark for protein stability

Formation and stability of helical poly (N^ϵ, N^ϵ, N^ϵ‐trimethyl‐L‐lysine) in sodium perchlorate solution

Helix formation in methylated copolymers of lysine and alanine

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Methylated Polyl(L-lysine): Conformational Effects and Interactions with Polynucleotides

Cited by 5 publications

References 32 publications

Methylation, a new epigenetic mark for protein stability

Methylation, a new epigenetic mark for protein stability

Formation and stability of helical poly (Nϵ, Nϵ, Nϵ‐trimethyl‐L‐lysine) in sodium perchlorate solution

Helix formation in methylated copolymers of lysine and alanine

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Formation and stability of helical poly (N^ϵ, N^ϵ, N^ϵ‐trimethyl‐L‐lysine) in sodium perchlorate solution