Protein Analytical Assays for Diagnosing, Monitoring, and Choosing Treatment for Cancer Patients

Powers, Alicia D.; Palecek, Sean P.

doi:10.1260/2040-2295.3.4.503

Cited by 51 publications

(24 citation statements)

References 128 publications

(266 reference statements)

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“…For precision medicine, PTM signatures may either be identified in disease models and then validated in clinical samples or directly identified using clinical samples. Although, for example, specific changes in phosphorylation and glycosylation are increasingly reported as potential markers of disease, and many PTM assays have been developed so far (for instance reviewed in [23][24][25]), only few are really routinely used for diagnostic purposes to date, due to a variety of reasons [26]. We are still in the early days of PTM-specific research and detection and many potential PTM biomarkers and the corresponding assays still need to be validated extensively.…”

Section: Can Ptms Be Used As Biomarkers?mentioning

confidence: 99%

Detecting post-translational modification signatures as potential biomarkers in clinical mass spectrometry

Mnatsakanyan

Shema

Basik

et al. 2018

Expert Review of Proteomics

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Numerous diseases are caused by changes in post-translational modifications (PTMs). Therefore, the number of clinical proteomics studies that include the analysis of PTMs is increasing. Combining complementary information-for example changes in protein abundance, PTM levels, with the genome and transcriptome (proteogenomics)-holds great promise for discovering important drivers and markers of disease, as variations in copy number, expression levels, or mutations without spatial/functional/isoform information is often insufficient or even misleading. Areas covered: We discuss general considerations, requirements, pitfalls, and future perspectives in applying PTM-centric proteomics to clinical samples. This includes samples obtained from a human subject, for instance (i) bodily fluids such as plasma, urine, or cerebrospinal fluid, (ii) primary cells such as reproductive cells, blood cells, and (iii) tissue samples/biopsies. Expert commentary: PTM-centric discovery proteomics can substantially contribute to the understanding of disease mechanisms by identifying signatures with potential diagnostic or even therapeutic relevance but may require coordinated efforts of interdisciplinary and eventually multi-national consortia, such as initiated in the cancer moonshot program. Additionally, robust and standardized mass spectrometry (MS) assays-particularly targeted MS, MALDI imaging, and immuno-MALDI-may be transferred to the clinic to improve patient stratification for precision medicine, and guide therapies.

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Section: Can Ptms Be Used As Biomarkers?mentioning

confidence: 99%

Detecting post-translational modification signatures as potential biomarkers in clinical mass spectrometry

Mnatsakanyan

Shema

Basik

et al. 2018

Expert Review of Proteomics

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“…12 Additionally, sample fixation has the potential to induce artificial patterns particularly for signalling PTMs such as protein phosphorylation, or, conversely, may fail to preserve these. In IHC, results are often interpreted in a semi-quantitative manner, and are manually ranked based on staining intensity which introduces subjectivity and variability into the assays, 13 with a continuing need for improved standardization. 14,15 Recently, Morales-Betanzos et al demonstrated that IHC methods for detecting programmed death-ligand 1 (PD-L1), an important companion diagnostics for immune checkpoint therapies, can suffer severely from interference by endogenous PD-L1 glycosylation patterns that prevent proper epitope recognition, leading to underestimation of PD-L1 expression levels.…”

Section: The Demand For Clinical Diagnostic Assaysmentioning

confidence: 99%

How iMALDI can improve clinical diagnostics

Popp

Basik

Spatz

et al. 2018

Analyst

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Protein mass spectrometry (MS) is an indispensable tool to detect molecular signatures that can be associated with cellular dysregulation and disease. Despite its huge success in the life sciences, where it has led to novel insights into disease mechanisms and the identification of potential protein biomarkers, protein MS is rarely used for clinical protein assays. While conventional matrix-assisted laser desorption/ionization (MALDI) MS is not compatible with complex samples, liquid chromatography-MS (LC-MS)-based assays may be too complex and may lack the robustness and ease of automation required for routine use in the clinic. Therefore, clinical protein assays are dominated by immunohistochemistry and immunoassays which, however, often lack standardization and fully depend on antibody specificity. Immuno-MALDI (iMALDI) MS may overcome these hurdles by utilizing anti-peptide antibodies for the specific enrichment of targeted analytes and on-target detection of the captured analytes, thus combining the unique properties of MS for the unambiguous detection and quantitation of analytes with a workflow that can be fully automated. Here we discuss the requirements for clinical protein assays, the pitfalls of existing methods, how iMALDI has been successfully used to quantify endogenous peptides and proteins from clinical samples, as well as its potential as a powerful tool for companion diagnostics in the light of precision medicine.

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“…Development of analytical methods for biomarkers such as proteins and peptides has great significance in the fields of clinical diagnostics, environmental monitoring, food safety tests, and proteomics . Immunoassays, which are those of the most common methods for protein analyses, can sensitively detect desired analytes, because proteins are recognized through antigen–antibody interactions in measurement systems.…”

Section: Figurementioning

confidence: 99%

Label‐Free Direct Electrical Detection of a Histidine‐Rich Protein with Sub‐Femtomolar Sensitivity using an Organic Field‐Effect Transistor

et al. 2017

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There is a growing interest in achieving sensor systems to enable on‐site testing of biomarkers. Herein, a new strategy for highly sensitive protein detection at sub‐femtomolar levels without any labelling has been demonstrated by using an organic field‐effect transistor (OFET). An artificial histidine‐rich protein receptor (NiII‐nitrilotriacetic acid complex, NiII‐nta) functionalizes a detection portion (i.e. an extended‐gate electrode) of the fabricated OFET device. The OFET responds electrically and selectively to a target analyte (bovine serum albumin), meaning that the binding processes at the NiII‐nta on the extended‐gate electrode for the analyte affect the field‐effect properties of the device. Our results demonstrate that the combination of the OFET with the artificial receptor is an ideal approach for label‐free and immune‐free protein detection.

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Protein Analytical Assays for Diagnosing, Monitoring, and Choosing Treatment for Cancer Patients

Cited by 51 publications

References 128 publications

Detecting post-translational modification signatures as potential biomarkers in clinical mass spectrometry

Detecting post-translational modification signatures as potential biomarkers in clinical mass spectrometry

How iMALDI can improve clinical diagnostics

Label‐Free Direct Electrical Detection of a Histidine‐Rich Protein with Sub‐Femtomolar Sensitivity using an Organic Field‐Effect Transistor

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