Protease cleavage site fingerprinting by label‐free in‐gel degradomics reveals
            <scp>pH</scp>
            ‐dependent specificity switch of legumain

Vidmar, Robert; Vizovišek, Matej; Turk, Dušan; Turk, Boris; Fonović, Marko

doi:10.15252/embj.201796750

Cited by 62 publications

(87 citation statements)

References 51 publications

(85 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Interestingly, around 5% of vertebrate cleavage site orthologs have glutamate in the P1 position instead of aspartate (Table 1). Previous in vitro reports have shown that caspases-3, -6, and -7 are able to accommodate P1 glutamate in the active site and cleave substrates with P1 E cut sites with the same affinity but with a twofold slower rate than substrates with aspartate in the same position [13,37]. The same study by the Wells group demonstrated that substitution of P1 glutamate by aspartate actually results in a higher rate of protein cleavage by caspases.…”

Section: Vertebrate Caspase Targets Are Highly Conserved At the Levelmentioning

confidence: 90%

Novel Apoptotic Mediators Identified by Conservation of Vertebrate Caspase Targets

et al. 2020

View full text Add to dashboard Cite

Caspases are proteases conserved throughout Metazoans and responsible for initiating and executing the apoptotic program. Currently, there are over 1800 known apoptotic caspase substrates, many of them known regulators of cell proliferation and death, which makes them attractive therapeutic targets. However, most caspase substrates are by-standers, and identifying novel apoptotic mediators amongst all caspase substrates remains an unmet need. Here, we conducted an in silico search for significant apoptotic caspase targets across different species within the Vertebrata subphylum, using different criteria of conservation combined with structural features of cleavage sites. We observed that P1 aspartate is highly conserved while the cleavage sites are extensively variable and found that cleavage sites are located primarily in coiled regions composed of hydrophilic amino acids. Using the combination of these criteria, we determined the final list of the 107 most relevant caspase substrates including 30 novel targets previously unknown for their role in apoptosis and cancer. These newly identified substrates can be potential regulators of apoptosis and candidates for anti-tumor therapy.

show abstract

Section: Vertebrate Caspase Targets Are Highly Conserved At the Levelmentioning

confidence: 90%

Novel Apoptotic Mediators Identified by Conservation of Vertebrate Caspase Targets

et al. 2020

View full text Add to dashboard Cite

show abstract

“…In the second step, the protease-generated peptides can be identified with any tandem mass spectra search tool. In our implementation, we used the Andromeda 30 search engine in MaxQuant 31 using unspecific database search parameters as described elsewhere 21 . Importantly, we searched the data with a reduced database (HTPS_DB.fasta) generated from proteins identified in Trypsin, Lys-C, Asp-N, Glu-C and Chymotrypsin samples.…”

Section: A Methods For High-throughput Screening Of Protease Substratementioning

confidence: 99%

“…Relevant techniques to identify protease substrates include COFRADIC (combined fractional diagonal chromatography) 10,11 , ChaFraDIC (charge-based fractional diagonal chromatography) 12 , PICS (proteomic identification of protease cleavage sites) 13,14 and TAILS (terminal amine isotopic labeling of substrates) 15,16 which are reviewed elsewhere [17][18][19] . More recently, workflows like FPPS (fast profiling of protease specificity) 20 and especially label-free degradomic workflows like DIPPS (direct in-gel profiling of protease specificity) 21 and ChaFraTip (ChaFraDIC performed in a pipet tip format) 22 made protease characterization easier and more accessible by describing simplified workflows and omitting extensive fractionation or labeling steps. Furthermore, DIPPS 21 and ChaFraTip 22 can simultaneously map prime and non-prime substrate sites by sequencing the protease-generated peptides.…”

Section: Introductionmentioning

confidence: 99%

“…More recently, workflows like FPPS (fast profiling of protease specificity) 20 and especially label-free degradomic workflows like DIPPS (direct in-gel profiling of protease specificity) 21 and ChaFraTip (ChaFraDIC performed in a pipet tip format) 22 made protease characterization easier and more accessible by describing simplified workflows and omitting extensive fractionation or labeling steps. Furthermore, DIPPS 21 and ChaFraTip 22 can simultaneously map prime and non-prime substrate sites by sequencing the protease-generated peptides. In spite of these developments, several limitations remain which limit the throughput, costeffectiveness or physiological relevance of these assays.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Mapping specificity, entropy, allosteric changes and substrates in blood proteases by a high-throughput protease screen

Uliana

Vizovišek

Acquasaliente

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

Proteases are among the largest protein families in eukaryotic phylae with more than 500 genetically encoded proteases in humans. By cleaving a wide range of target proteins, proteases are critical regulators of a vast number of biochemical processes including apoptosis and blood coagulation. Over the last 20 years, knowledge of proteases has been drastically expanded by the development of proteomic approaches to identify and quantify proteases and their substrates. In spite of their merits, some of these methods are laborious, not scalable or incompatible with native environments. Consequentially, a large number of proteases remain poorly characterized. Here, we introduce a simple proteomic method to profile protease activity based on isolation of protease products from native lysates using a 96FASP filter and their analysis in a mass spectrometer. The method is significantly faster, cheaper, technically less demanding, easily multiplexed and produces accurate protease fingerprints in near-native conditions. By using the blood cascade proteases as a case study we obtained protease substrate profiles of unprecedented depth that can be reliably used to map specificity, entropy and allosteric changes of the protease and to design fluorescent probes and predict physiological substrates. The native protease characterization method is comparable in performance, but largely exceeds the throughput of current alternatives.

show abstract

“…Four kidney samples selected as most representative from each treatment group and four control kidney samples were processed for mass spectrometry analysis as described before [79] with a slightly modified protocol. Frozen tissues were cut into pieces of about 30 mg on dry ice to prevent thawing.…”

Section: Tissue Homogenizationmentioning

confidence: 99%

The Acute Phase Response Is a Prominent Renal Proteome Change in Sepsis in Mice

Róka

Tod

Kaucsár

et al. 2019

IJMS

Self Cite

View full text Add to dashboard Cite

(1) Background: Sepsis-induced acute kidney injury (AKI) is the most common form of acute kidney injury (AKI). We studied the temporal profile of the sepsis-induced renal proteome changes. (2) Methods: Male mice were injected intraperitoneally with bacterial lipopolysaccharide (LPS) or saline (control). Renal proteome was studied by LC-MS/MS (ProteomeXchange: PXD014664) at the early phase (EP, 1.5 and 6 h after 40 mg/kg LPS) and the late phase (LP, 24 and 48 h after 10 mg/kg LPS) of LPS-induced AKI. Renal mRNA expression of acute phase proteins (APP) was assessed by qPCR. (3) Results: Renal proteome change was milder in EP vs. LP. APPs dominated the proteome in LP (proteins upregulated at least 4-fold (APPs/all): EP, 1.5 h: 0/10, 6 h: 1/10; LP, 24 h: 22/47, 48 h: 17/44). Lipocalin-2, complement C3, fibrinogen, haptoglobin and hemopexin were the most upregulated APPs. Renal mRNA expression preceded the APP changes with peak effects at 24 h, and indicated renal production of the majority of APPs. (4) Conclusions: Gene expression analysis revealed local production of APPs that commenced a few hours post injection and peaked at 24 h. This is the first demonstration of a massive, complex and coordinated acute phase response of the kidney involving several proteins not identified previously.

show abstract

Protease cleavage site fingerprinting by label‐free in‐gel degradomics reveals pH ‐dependent specificity switch of legumain

Cited by 62 publications

References 51 publications

Novel Apoptotic Mediators Identified by Conservation of Vertebrate Caspase Targets

Novel Apoptotic Mediators Identified by Conservation of Vertebrate Caspase Targets

Mapping specificity, entropy, allosteric changes and substrates in blood proteases by a high-throughput protease screen

The Acute Phase Response Is a Prominent Renal Proteome Change in Sepsis in Mice

Contact Info

Product

Resources

About