Biocatalysis: Mechanisms of Proteolytic Enzymes

A special issue of Catalysts (ISSN 2073-4344). This special issue belongs to the section "Biocatalysis".

Deadline for manuscript submissions: closed (31 October 2020) | Viewed by 10124

Special Issue Editor


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Guest Editor
Structural Biology Group, Department of Biosciences, University of Salzburg, Billrothstrasse 11, 5020 Salzburg, Austria
Interests: protein crystallography, proteases, kallikrein-related peptidases, metalloproteinases, enzyme kinetics, inhibitors, gylcosylation, human physiology, protein folding
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Special Issue Information

Dear Colleagues,

Proteases are traditionally among the most studied enzymes and over the decades a wealth of structural, functional and theoretical information has accumulated. However, the understanding of the molecular mechanisms underlying their activities and regulation remains incomplete. Although the basic principles of peptide bond hydrolysis were delineated a long time ago, there is a lack of experimental evidence for many aspects of substrate recognition, turnover, energetics, time course of the catalytic steps, and of the fine-tuned physiological regulation of activity. Thus, it is worth investigating and comparing the molecular mechanisms for the numerous serine, cysteine, metallo and aspartic proteases, as well as for the much rarer threonine, asparagine and glutamic type. In order to add more biological and medical relevance, we welcome articles that analyze molecular interactions of proteases with natural substrates and inhibitors or their synthetic small molecule counterparts.

The goal of this Special Issue is to present experimental, computational and comparative studies, which promote a deeper understanding of the common mechanistic principles of proteases. Also, structural and analytical data from crystallography, cryo-EM, NMR and MS that support functional and mechanistic research are welcome. Therefore, submissions to this Special Issue on the “Biocatalysis: Mechanisms of Proteolytic Enzymes” should be either original research papers, including short communications, or reviews and perspectives. Eventually, we hope to draw a topical picture of the current status and developments, which could have an impact on other fields of research, such as medicine and pharmacy.

Accepted papers are published in the joint Special Issue in Catalysts or International Journal of Molecular Sciences.

Dr. Peter Goettig
Guest Editor

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Keywords

  • aspartic proteases
  • catalytic mechanism
  • conformational selection
  • cysteine proteases
  • enzyme kinetics
  • metalloproteases
  • nucleophilic attack
  • peptide bond hydrolysis
  • serine protease

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Published Papers (2 papers)

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Research

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15 pages, 629 KiB  
Article
The Evolution, Gene Expression Profile, and Secretion of Digestive Peptidases in Lepidoptera Species
by Lucas R. Lima, Renata O. Dias, Felipe Jun Fuzita, Clélia Ferreira, Walter R. Terra and Marcio C. Silva-Filho
Catalysts 2020, 10(2), 217; https://doi.org/10.3390/catal10020217 - 11 Feb 2020
Cited by 6 | Viewed by 2602
Abstract
Serine peptidases (SPs) are responsible for most primary protein digestion in Lepidoptera species. An expansion of the number of genes encoding trypsin and chymotrypsin enzymes and the ability to upregulate the expression of some of these genes in response to peptidase inhibitor (PI) [...] Read more.
Serine peptidases (SPs) are responsible for most primary protein digestion in Lepidoptera species. An expansion of the number of genes encoding trypsin and chymotrypsin enzymes and the ability to upregulate the expression of some of these genes in response to peptidase inhibitor (PI) ingestion have been associated with the adaptation of Noctuidae moths to herbivory. To investigate whether these gene family expansion events are common to other Lepidoptera groups, we searched for all genes encoding putative trypsin and chymotrypsin enzymes in 23 publicly available genomes from this taxon. Phylogenetic analysis showed that several gene family expansion events may have occurred in the taxon’s evolutionary history and that these events gave rise to a very diverse group of enzymes, including proteins lacking the canonical SP catalytic triad. The expression profile of these enzymes along the midgut and the secretion mechanisms by which these enzymes enter the luminal content were also analyzed in Spodoptera frugiperda larvae using RNA-seq and proteomics. These results support the proposal of a midgut countercurrent flux responsible for the direction of these proteins to the anterior portion of the midgut and show that these enzymes reach the midgut lumen via both exocytosis and microapocrine secretion mechanisms. Full article
(This article belongs to the Special Issue Biocatalysis: Mechanisms of Proteolytic Enzymes)
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Review

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18 pages, 4955 KiB  
Review
Reversed Proteolysis—Proteases as Peptide Ligases
by Peter Goettig
Catalysts 2021, 11(1), 33; https://doi.org/10.3390/catal11010033 - 30 Dec 2020
Cited by 11 | Viewed by 6894
Abstract
Historically, ligase activity by proteases was theoretically derived due to their catalyst nature, and it was experimentally observed as early as around 1900. Initially, the digestive proteases, such as pepsin, chymotrypsin, and trypsin were employed to perform in vitro syntheses of small peptides. [...] Read more.
Historically, ligase activity by proteases was theoretically derived due to their catalyst nature, and it was experimentally observed as early as around 1900. Initially, the digestive proteases, such as pepsin, chymotrypsin, and trypsin were employed to perform in vitro syntheses of small peptides. Protease-catalyzed ligation is more efficient than peptide bond hydrolysis in organic solvents, representing control of the thermodynamic equilibrium. Peptide esters readily form acyl intermediates with serine and cysteine proteases, followed by peptide bond synthesis at the N-terminus of another residue. This type of reaction is under kinetic control, favoring aminolysis over hydrolysis. Although only a few natural peptide ligases are known, such as ubiquitin ligases, sortases, and legumains, the principle of proteases as general catalysts could be adapted to engineer some proteases accordingly. In particular, the serine proteases subtilisin and trypsin were converted to efficient ligases, which are known as subtiligase and trypsiligase. Together with sortases and legumains, they turned out to be very useful in linking peptides and proteins with a great variety of molecules, including biomarkers, sugars or building blocks with non-natural amino acids. Thus, these engineered enzymes are a promising branch for academic research and for pharmaceutical progress. Full article
(This article belongs to the Special Issue Biocatalysis: Mechanisms of Proteolytic Enzymes)
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