Prozessive Katalyse

Dongen, Stijn F. M. van; Elemans, Johannes A. A. W.; Rowan, Alan E.; Nolte, Roeland J. M.

doi:10.1002/ange.201404848

“…This can be attained, for example, with a nanopore that transforms a coded macromolecular sequence into an electrical signal [11] . Afterwards, the transmitted signal can be exploited for the synthesis of a sequence‐defined macromolecular replicate; for example with the help of processive catalysis [12] . Although never achieved, such a contact‐free mechanism may potentially also lead to macromolecular information transfer.…”

Section: General Mechanismsmentioning

confidence: 99%

Macromolecular Information Transfer

Samokhvalova

¹

,

Lutz

²

2023

View full text Add to dashboard Cite

Macromolecular information transfer can be defined as the process by which a coded monomer sequence is communicated from one macromolecule to another. In such a transfer process, the information sequence can be kept identical, transformed into a complementary sequence or even translated into a different molecular language. Such mechanisms are crucial in biology and take place in DNA!DNA replication, DNA!RNA transcription and RNA! protein translation. In fact, there would be no life on Earth without macromolecular information transfer. Mimicking such processes with synthetic macromolecules would also be of major scientific relevance because it would open up new avenues for technological applications (e.g. data storage and processing) but also for the creation of artificial life. In this important context, this minireview summarizes recent research about information transfer in synthetic oligomers and polymers. Medium-and long-term perspectives are also discussed.

show abstract

Macromolecular Information Transfer

Samokhvalova

¹

,

Lutz

²

2023

Angewandte Chemie

2

0

View full text Add to dashboard Cite

Macromolecular information transfer can be defined as the process by which a coded monomer sequence is communicated from one macromolecule to another. In such a transfer process, the information sequence can be kept identical, transformed into a complementary sequence or even translated into a different molecular language. Such mechanisms are crucial in biology and take place in DNA!DNA replication, DNA!RNA transcription and RNA! protein translation. In fact, there would be no life on Earth without macromolecular information transfer. Mimicking such processes with synthetic macromolecules would also be of major scientific relevance because it would open up new avenues for technological applications (e.g. data storage and processing) but also for the creation of artificial life. In this important context, this minireview summarizes recent research about information transfer in synthetic oligomers and polymers. Medium-and long-term perspectives are also discussed.

show abstract

Kinetic Analysis of PRMT1 Reveals Multifactorial Processivity and a Sequential Ordered Mechanism

Brown

¹

,

Koopmans

²

,

Strien³

et al. 2017

View full text Add to dashboard Cite

Arginine methylation is a prevalent post‐translational modification in eukaryotic cells. Two significant debates exist within the field: do these enzymes dimethylate their substrates in a processive or distributive manner, and do these enzymes operate using a random or sequential method of bisubstrate binding? We revealed that human protein arginine N‐methyltransferase 1 (PRMT1) enzyme kinetics are dependent on substrate sequence. Further, peptides containing an Nη‐hydroxyarginine generally demonstrated substrate inhibition and had improved KM values, which evoked a possible role in inhibitor design. We also revealed that the perceived degree of enzyme processivity is a function of both cofactor and enzyme concentration, suggesting that previous conclusions about PRMT sequential methyl transfer mechanisms require reassessment. Finally, we demonstrated a sequential ordered Bi–Bi kinetic mechanism for PRMT1, based on steady‐state kinetic analysis. Together, our data indicate a PRMT1 mechanism of action and processivity that might also extend to other functionally and structurally conserved PRMTs.

show abstract

Prozessive Katalyse

Cited by 9 publications

References 39 publications

Macromolecular Information Transfer

Macromolecular Information Transfer

Macromolecular Information Transfer

Kinetic Analysis of PRMT1 Reveals Multifactorial Processivity and a Sequential Ordered Mechanism

Contact Info

Product

Resources

About