Conformational fingerprint of blood and tissue ACEs: Personalized approach

Danilov, Sergei M.; Tikhomirova, Victoria E.; Kryukova, Olga; Balatsky, Alexander V.; Bulaeva, Naida I.; Голухова, Е.З.; Bokeria, L. A.; Samokhodskaya, L М; Кост, О. А.

doi:10.1371/journal.pone.0209861

Cited by 10 publications

(20 citation statements)

References 41 publications

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“…Cell and tissue specificity of these enzymes suggests that each type (including probably malignant cells) have a unique “sialome” which may be used to document cell origin or pathology [47]. Our hypothesis, that observed changes in binding of mAb 3F10 to ACE from BPH and PC prostate tissues (Figure 4) are due to hypersialylation of ACE molecules is supported by the finding that this very mAb bind better to plasma ACE than to lung ACE (Figure 10A in [35], and plasma ACE is known to be more sialylated than its “parent” lung enzyme as a result of elimination of less sialylated proteins from the blood by liver lectins [48].…”

Section: Resultsmentioning

confidence: 77%

“…As a result, the ratio of the rates of hydrolysis of these two substrates (ZPHL/HHL ratio) serves as a characteristic of a definite ACE form: for somatic two-domain human ACE it is about 1-1.5, for N domain – 5-7, and C domain – 0.6-0.8 [27]. The ZPHL/HHL ratio used primarily to detect the presence of common ACE inhibitors taken as a drug in patients’ blood at the time of blood sampling [27, 34, 35]. This parameter can also help to detect inactivation or inhibition of a separate domain, as the increase of this ratio can indicate inactivation/inhibition of the C domain, while the decrease of this ratio may be an indicator for inactivation/inhibition of N domain [27].…”

Section: Resultsmentioning

confidence: 99%

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Tissue ACE phenotyping in prostate cancer

et al. 2019

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Epithelial cells of prostate express significant level of ACE and, as a result, seminal fluid has 50-fold more ACE than plasma. The substitution of highly specialized prostate epithelial cells by tumor cells results in dramatic decrease in ACE production in prostate tissues. We performed detailed characterization of ACE status in prostate tissues from patients with benign prostate hyperplasia (BPH) and prostate cancer (PC) using new approach- ACE phenotyping, that includes evaluation of: 1) ACE activity with two substrates (HHL and ZPHL); 2) the ratio of the rates of their hydrolysis (ZPHL/HHL ratio); 3) the ratio of immunoreactive ACE protein to ACE activity; 4) the pattern of mAbs binding to different epitopes on ACE – ACE conformational fingerprint - to reveal conformational changes in prostate ACE due to prostate pathology. ACE activity dramatically decreased and the ratio of immunoreactive ACE protein to ACE activity increased in PC tissues. The catalytic parameter, ZPHL/HHL ratio, increased in prostate tissues from all patients with PC, but was did not change for most |BPH patients. Nevertheless, prostate tissues of several patients diagnosed with BPH based on histology, also demonstrated decreased ACE activity and increased immunoreactive ACE protein/ACE activity and ZPHL/HHL ratios, that could be considered as more early indicators of prostate cancer development than routine histology. Thus, ACE phenotyping of prostate biopsies has a potential to be an effective approach for early diagnostics of prostate cancer or at least for differential diagnostics of BPH and PC.

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Section: Resultsmentioning

confidence: 77%

Section: Resultsmentioning

confidence: 99%

Tissue ACE phenotyping in prostate cancer

et al. 2019

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“…The pattern of glycosylation of ACE produced in various tissues and, therefore, ACE ability to bind monoclonal antibodies to different regions on the protein globule can vary significantly [29,[32][33][34][35] due to the differences in posttranslational modification of the enzyme in different types of cells. Thus, ACE can be considered as a perspective biomarker of various diseases and by now identification of cell-specific ACE in the blood by the panel of monoclonal antibodies was successfully demonstrated on the examples of sarcoidosis [28,36] and Gaucher disease.…”

Section: Introductionmentioning

confidence: 99%

Human angiotensin I‐converting enzyme study by surface‐enhanced Raman spectroscopy

Boginskaya

Nechaeva

Tikhomirova

et al. 2021

J Raman Spectroscopy

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Angiotensin I‐converting enzyme (ACE) is a glycoprotein, consisting of two homologous domains within a single polypeptide chain. ACE concentration in biological fluids is an important parameter of clinical observation; its increase or decrease may accompany various pathologies. Currently, the exact crystal structure of the two‐domain ACE form is still unknown because of microheterogeneity and intensity of the enzyme glycosylation. Raman spectroscopy provides the qualitative and quantitative analysis of many compounds, including proteins. For the first time, surface‐enhanced Raman scattering (SERS) spectra of native and thermo‐denatured human ACE have been demonstrated with full assignment. Denaturation leads to SERS intensity increase and bands shifting. Detailed band assignment and discussion are included to elucidate the potential site of ACE interaction with the silver surface. Based on SERS spectra, we characterized the region on the ACE molecule in contact with the substrate and demonstrated the model of the two‐domain ACE adsorbed on a silver matrix.

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“…We hypothesized that particular differences in mAbs 1B8 and 3F10 binding to lung cancer ACE (Fig 4) may result from greater extent of sialylation of glycan in Asn731 in tumor. This possibility arise from the observation that these very mAbs better bind to plasma ACE than to lung ACE (Fig 10A in [55]), and plasma ACE is known to be more sialylated than its “parent” lung enzyme as a result of elimination of unsialylated proteins from plasma by liver lectins [56].…”

Section: Resultsmentioning

confidence: 99%

Tissue ACE phenotyping in lung cancer

et al. 2019

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BackgroundPulmonary vascular endothelium is the main metabolic site for Angiotensin I-Converting Enzyme (ACE)-mediated degradation of several biologically-active peptides (angiotensin I, bradykinin, hemo-regulatory peptide Ac-SDKP). Primary lung cancer growth and lung cancer metastases decrease lung vascularity reflected by dramatic decreases in both lung and serum ACE activity. We performed precise ACE phenotyping in tissues from subjects with lung cancer.MethodologyACE phenotyping included: 1) ACE immunohistochemistry with specific and well-characterized monoclonal antibodies (mAbs) to ACE; 2) ACE activity measurement with two ACE substrates (HHL, ZPHL); 3) calculation of ACE substrates hydrolysis ratio (ZPHL/HHL ratio); 4) the pattern of mAbs binding to 17 different ACE epitopes to detect changes in ACE conformation induced by tumor growth (conformational ACE fingerprint).ResultsACE immunostaining was dramatically decreased in lung cancer tissues confirmed by a 3-fold decrease in ACE activity. The conformational fingerprint of ACE from tumor lung tissues differed from normal lung (6/17 mAbs) and reflected primarily higher ACE sialylation. The increase in ZPHL/HHL ratio in lung cancer tissues was consistent with greater conformational changes of ACE. Limited analysis of the conformational ACE fingerprint in normal lung tissue and lung cancer tissue form the same patient suggested a remote effect of tumor tissue on ACE conformation and/or on “field cancerization” in a morphologically-normal lung tissues.Conclusions/SignificanceLocal conformation of ACE is significantly altered in tumor lung tissues and may be detected by conformational fingerprinting of human ACE.

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Conformational fingerprint of blood and tissue ACEs: Personalized approach

Cited by 10 publications

References 41 publications

Tissue ACE phenotyping in prostate cancer

Tissue ACE phenotyping in prostate cancer

Human angiotensin I‐converting enzyme study by surface‐enhanced Raman spectroscopy

Tissue ACE phenotyping in lung cancer

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