Soluble Semaphorin 4D ELISA
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Method
Sandwich ELISA, HRP/TMB, 12×8-well detachable strips
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Sample type
EDTA plasma, citrate plasma, heparin plasma, cell culture supernatant
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Sample volume
10 µl / well
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Assay time
20 min / 3 h / 30 min
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Sensitivity
12 pmol/l (= 947 pg/ml)
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Standard range
0 – 2,000 pmol/l (= 0 – 157,800 pg/ml)
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Conversion factor
1 pg/ml = 0.0127 pmol/l (MW: 78.9 kDa)
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Specificity
Endogenous and recombinant human soluble Semaphorin 4D.
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Precision
In-between-run (n=11): ≤ 11 % CV
Within-run (n=5): ≤ 8 % CV
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Use
Research use only.
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Validation Data
See validation data tab for: precision, accuracy, dilution linearity, values for healthy donors, etc
Product Overview
The soluble Semaphorin 4D immunoassay is a 4.5 hour, 96-well sandwich ELISA for the quantitative determination of soluble Sempahorin 4D (sSEMA4D) in EDTA plasma, citrate plasma, heparin plasma and cell culture supernatant. The assay employs human plasma-based standards to ensure the measurement of biologically reliable data.
The soluble Semaphorin 4D kit uses highly purified, epitope mapped antibodies. The antibodies utilized in the soluble Semaphorin 4D kit bind to AA30-AA34 and AA238-AA241 of soluble Semaphorin 4D.
Principle of the Assay
This kit is a sandwich enzyme immunoassay for the quantitative determination of soluble Semaphorin 4D in human plasma and cell culture supernatant.
The figure below explains the principle of the soluble Semaphorin 4D sandwich ELISA:
In a first step, standard/control/sample is pipetted into the wells of the microtiter strips, which are pre-coated with monoclonal mouse anti-human Semaphorin 4D antibody. Semaphorin 4D present in the standard/control/sample binds to the pre-coated antibody in the well. In the washing step all non-specific unbound material is removed. In a next step, the conjugate (bivalent Fab bacterial alkaline phosphatase fusion antibody-HRP) is pipetted into the wells and reacts with the soluble Semaphorin 4D forming a sandwich. After another washing step, the substrate (TMB, tetramethylbenzidine) is pipetted into the wells. The enzyme-catalyzed color change of the substrate is directly proportional to the amount of Semaphorin 4D present in the sample. This color change is detectable with a standard microtiter plate reader. A dose response curve of the absorbance (optical density, OD at 450 nm) vs. standard concentration is generated. The concentration of OPG in the sample is determined directly from the dose response curve.
The soluble Semaphorin 4D kit uses highly purified, epitope-mapped antibodies. The antibodies utilized in the soluble Semphorin 4D ELISA (BI-20405) are as follows:
Capture antibody: monoclonal mouse anti-human Semaphorin 4D (epitope: AA30-34 of Uniprot ID Q92854)
Detection antibody: bivalent Fab bacterial alkaline phosphatase fusion antibody-HRP (epitope: AA238-241 of Uniprot ID Q92854)
Typical Standard Curve
The figure below shows a typical standard curve for the soluble Semaphorin 4D ELISA. The immunoassay is calibrated against recombinant human Semaphorin 4D:
ELISA Kit Components
CONTENT |
DESCRIPTION |
QUANTITY |
PLATE |
Monoclonal mouse anti-human Semaphorin 4D antibody pre-coated microtiter strips in a strip holder, packed in an aluminum bag with desiccant |
12 x 8 tests |
WASHBUF |
20x wash buffer concentrate, natural cap |
1 x 50 ml |
STD |
Standards 1-7, (0; 62.5; 125; 250; 500; 1,000; 2,000 pmol/l), recombinant human soluble Semaphorin 4D in human plasma, white caps, lyophilized |
7 vials |
CTRL |
Control A+B, yellow caps, lyophilized, exact concentration see labels |
2 vials |
ASYBUF |
Assay buffer, red cap, ready to use |
1 x 13 ml |
CONJ |
Conjugate (bivalent Fab bacterial alkaline phosphatase fusion antibody-HRP), amber bottle, amber cap, ready to use |
1 x 13 ml |
SUB |
Substrate (TMB solution), blue cap, ready to use |
1 x 13 ml |
STOP |
STOP solution, white cap, ready to use |
1 x 7 ml |
Storage instructions: All reagents of the soluble Semaphorin 4D ELISA kit are stable at 4°C until the expiry date stated on the label of each reagent.
EDTA plasma, heparin plasma, citrate plasma and cell culture supernatant are suitable for use in this assay. Do not change sample type during studies. We recommend duplicate measurements for all samples, standards and controls. The sample collection and storage conditions listed are intended as general guidelines.
Plasma
Collect venous blood samples in standardized blood collection tubes using EDTA, heparin or citrate as an anticoagulant. Perform separation by centrifugation according to the tube manufacturer’s instructions for use. Assay the acquired samples immediately or aliquot and store at -25°C or lower. Lipemic or haemolyzed samples may give erroneous results. Do not freeze-thaw samples more than four times.
Cell Culture Supernatant
Remove particulates by centrifugation and assay immediately or aliquot and store samples at
-25°C or lower. Do not freeze-thaw samples more than four times.
Reagent Preparation
Wash Buffer
1. |
Bring the WASHBUF concentrate to room temperature. Crystals in the buffer concentrate will dissolve at room temperature. |
2. |
Dilute the WASHBUF concentrate 1:20, e.g. 50 ml WASHBUF + 950 ml distilled or deionized water. Only use diluted WASHBUF when performing the assay. |
The diluted WASHBUF is stable up to one month at 4°C (2-8°C).
Standards for Plasma Measurements
1. |
Pipette 200 µl of distilled or deionized water into each standard (STDs) and control (CTRL) vial. The exact concentration is printed on the label of each vial. |
2. |
Leave at room temperature (18-26°C) for 15 min. Vortex gently. Make sure that the lyophilisate is completely dissolved. |
Reconstituted STDs and CTRLs are stable at -25°C or lower until expiry date stated on the label. STDs and CTRLs are stable for five freeze-thaw cycles.
Standards for Cell Culture Supernatant Measurements
For the preparation of a cell culture-based standard curve always use the identical cell culture medium (CCM) as used for the experiment.
1. |
Reconstitute standard 7 (STD7) in 200 µl deionized water. Leave at room temperature (18-26°C) for 15 min and mix well before making dilutions. Use polypropylene tubes. |
2. |
Mark tubes ccSTD6 to ccSTD1. Dispense 50 µl cell culture medium into each vial. |
3. |
Pipette 50 µl of STD7 into tube marked as ccSTD6. Mix thoroughly. |
4. |
Transfer 50 µl of ccSTD6 into the tube marked as ccSTD5. Mix thoroughly. |
5. |
Continue in the same fashion to obtain ccSTD4 to ccSTD 2. CCM serves as the ccSTD1 (0 pmol/l soluble Semaphorin 4D). |
6. |
Using the prepared standards, follow the protocol as indicated for serum, plasma and urine samples. |
Attention: Supplied STD1-STD7 and controls are only valid for serum, plasma and urine and should not be used for cell culture measurements.
Sample Preparation
Bring samples to room temperature and mix samples gently to ensure the samples are homogenous. We recommend duplicate measurements for all samples. Samples for which the optical density (OD) value exceeds the highest point of the standard range (STD7, 2,000 pmol/l) can be diluted with ASYBUF (assay buffer).
Assay Protocol
Read the entire protocol before beginning the assay.
1. |
Bring reagents and samples to room temperature (18-26°C). |
2. |
Mark position for STD/CTRL/SAMPLE (standard/control/sample) on the protocol sheet. |
3. |
Take microtiter strips out of the aluminum bag. Store unused strips with desiccant at 4°C in the aluminum bag. Strips are stable until expiry date stated on the label. |
4. |
Pipette 100 µl ASYBUF (assay buffer, red cap) into each well. |
5. |
Add 10 µl STD/CTRL/SAMPLE in duplicates into the respective wells, swirl gently. |
6. |
Cover the plate tightly, swirl gently and incubate for 3 hours at room temperature (18-26°C). |
7. |
Aspirate and wash wells 5 x with 300 µl diluted WASHBUF. After the final wash, remove the remaining WASHBUF by strongly tapping plate against a paper towel. |
8. |
Add 100 µl CONJ (conjugate, amber cap) into each well, swirl gently. |
9. |
Cover tightly and incubate for 1 hour at room temperature in the dark. |
10. |
Aspirate and wash wells 5x with 300 µl diluted WASHBUF. After the final wash, remove remaining WASHBUF by strongly tapping plate against a paper towel. |
11. |
Add 100 µl SUB (substrate, blue cap) into each well. |
12. |
Incubate for 30 min at room temperature in the dark. |
13. |
Add 50 µl STOP (stop solution, white cap) into each well. |
14. |
Measure absorbance immediately at 450 nm with reference 630 nm, if available. |
Calculation of Results
Read the optical density (OD) of all wells on a plate reader using 450 nm wavelength (reference wavelength 630 nm). Construct a standard curve from the absorbance read-outs of the standards using commercially available software capable of generating a four-parameter logistic (4-PL) fit. Alternatively, plot the standards’ concentration on the x-axis against the mean absorbance for each standard on the y-axis and draw a best fit curve through the points on the graph. Curve fitting algorithms other than 4-PL have not been validated and will need to be evaluated by the user.
Obtain sample concentrations from the standard curve. If required, pmol/l can be converted into pg/ml by applying a conversion factor (1 pg/ml =0.00127 pmol/l (MW: 78.9 kDa)). Respective dilution factors have to be considered when calculating the final concentration of the sample.
The quality control (QC) protocol supplied with the kit shows the results of the final release QC for each kit lot. Data for OD obtained by customers may differ due to various influences and/or due to the normal decrease of signal intensity during shelf life. However, this does not affect validity of results as long as an OD of 1.50 or more is obtained for STD7 and the values of the CTRLs are in range (target ranges see labels).
INFORMATION ON THE ANALYTE
Semaphorin 4D Protein
Semaphorin 4D (SEMA4D or CD100) is a member of a family of transmembrane and secreted proteins that regulates key cellular functions and is involved in cell-cell communication (Kruger et al., 2005; Nkyimbeng-Takwi and Chapoval, 2011; Yazdani and Terman, 2006). Most of the effects of SEMA4D is mediated by plexins (Janssen et al., 2012; Suzuki et al., 2008). SEMA4D participates in numerous physiological processes such as axon guidance, immune regulation, angiogenesis, tumor progression, and bone metabolism (Conrotto et al., 2005; Negishi-Koga et al., 2011a; Negishi-Koga and Takayanagi, 2012; Takamatsu and Kumanogoh, 2012). Cleavage of SEMA4D near the cell membrane through matrix metalloproteinases leads to the biologically active soluble SEMA4D with a molecular weight of 120 kD consisting of 713 amino acids (Maleki et al., 2016; Nkyimbeng-Takwi and Chapoval, 2011; Suzuki et al., 2008). SEMA4D has emerged to a novel therapeutic target in cancer and in bone diseases (Fisher et al., 2016; Yufeng Zhang et al., 2015). Semaphorin 4D is widely studied for its role in neural connectivity, vascularization, cell migration, the immune response, tumor progression, and bone remodeling.
Molecular Weight |
78.9 kDa |
Cellular localisation |
Cell membrane, extracellular |
Post-translational modifications |
Glycosylation |
Sequence similarities |
Semaphorins |
Alternative Names |
Semaphorin 4D, Semaphorin-4D, C9orf164, SEMAJ, CD100, BB18, GR3, CD100 Antigen, M-Sema-G, M-Sema G, Coll-4, COLL4 |
Entrez/NCBI ID |
10507: http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=gene&cmd=Retrieve&dopt=full_report&list_uids=10507 |
Genecards |
SEMA4D: https://www.genecards.org/cgi-bin/carddisp.pl?gene=SEMA4D |
OMIM |
601866: http://omim.org/entry/601866 |
PDB |
1OLZ: http://www.rcsb.org/structure/1OLZ |
Pfam |
Sema(PF01403): https://pfam.xfam.org/family/PF01403 |
Protein Atlas |
SEMA4D: https://www.proteinatlas.org/ENSG00000187764-SEMA4D/cell#rna |
Uniport ID |
Semaphorin 4D Function
Semaphorin 4D (Sema4D, CD100) is a type I integral membrane glycoprotein expressed as a disulphide-linked homodimer. It is over-expressed in a wide variety of cancers including malignancies of prostate, colon, breast, lung, and pancreas, as well as cervical and ovarian malignancies, head and neck squamous cell carcinoma, and osteosarcoma (Basile et al., 2006; Campos et al., 2013; Kato et al., 2011; Liu et al., 2014; Moriarity et al., 2015).
The extracellular region of Sema4D can be proteolytically cleaved to generate soluble molecule retaining its biological activity (Basile et al., 2007). The type 1 matrix metalloproteinases mediating this cleavage are upregulated in many malignant cells (Arribas and Esselens, 2009; Strongin, 2010). Among the three receptors binding soluble and transmembrane Semaphorin 4D, Plexin B1 has the highest affinity and is expressed on antigen presenting cells, endothelial and epithelial cells, as well as on some cancer cells (Ch’ng and Kumanogoh, 2010; Conrotto, 2005; Tamagnone et al., n.d.).
Sema4D activates endothelial cells and promotes tumor angiogenesis and tumor progression(Basile et al., 2006, 2004; Conrotto, 2005). Furthermore, it influences vascular permeability and might thereby regulate extravasation(Zhou et al., 2014). Apart from its pro-angiogenic properties, Sema4D acts on receptor-positive malignant cells where it promotes survival, proliferation, and migration (Capparuccia and Tamagnone, 2009; Chen et al., 2018; Damola et al., 2013; Takada et al., 2017). Within the tumor microenvironment Sema4D influences the infiltration and differentiation of immune cells creating an anti-inflammatory milieu (Chen et al., 2013; Delaire et al., 2001; Evans et al., 2015). Moreover, Sema4D suppresses osteoblast differentiation and hence, promotes the formation of bone metastasis (Negishi-Koga et al., 2011b; Takada et al., 2017; Yang et al., 2016a).
Elevated expression of Sema4D is generally associated with a poor prognosis in several malignancies (Chen et al., 2012, 2013; Kato et al., 2011; Liu et al., 2014; Wang et al., 2015). However, as a therapeutic target, interferences with Sema4D signaling provides the possibility to enhance anti-tumor immune responses and inhibit tumor progression (Evans et al., 2015; Patnaik et al., 2016). Recently, high expression of soluble Sema4D in the plasma of patients with head and neck squamous cell carcinoma has been reported (Derakhshandeh et al., 2018). This finding indicates that determination of Sema4D plasma levels might be useful tool to further study the role of Sema4D in the context of cancer progression, prognosis, and therapy.
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Cardiology
Atrial fibrillation (Xiang et al., 2015)
Heart failure (Lu et al., 2013)
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Immunology
Systemic sclerosis (Besliu et al., 2011)
Rheumatoid arthritis (Ha et al., 2018; Yoshida et al., 2015)
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Oncology
Breast cancer (Jiang et al., 2016; Malik et al., 2015; Yang et al., 2016b)
Cervical cancer (Liu et al., 2014)
Colorectal cancer (Ding et al., 2016; Ikeya et al., 2016; Wang et al., 2015)
Epithelial ovarian cancer (Chen et al., 2018, 2013, 2012)
Gastric cancer (Li et al., 2018)
Head and neck cancer (Derakhshandeh et al., 2018)
Lung cancer (Chen et al., 2019)
Multiple myeloma (Terpos et al., 2018)
Oral squamous cancer (Zhou et al., 2017)
Pancreatic cancer (Kato et al., 2011)
Prostate cancer (Damola et al., 2013)
Soft tissue sarcomas (Campos et al., 2013)
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Osteology
Osteoporosis (Yiyuan Zhang et al., 2015)
Literature
Sema4D expression and secretion are increased by HIF-1α and inhibit osteogenesis in bone metastases of lung cancer.
Chen, W.-G., Sun, J., Shen, W.-W., Yang, S.-Z., Zhang, Y., Hu, X., Qiu, H., Xu, S.-C., Chu, T.-W., 2019. Clin. Exp. Metastasis.
PMID: 30617444
VEGF and SEMA4D have synergistic effects on the promotion of angiogenesis in epithelial ovarian cancer.
Chen, Y., Zhang, L., Liu, W., Wang, K., 2018. Cell. Mol. Biol. Lett. 23.
Semaphorin 4D in human head and neck cancer tissue and peripheral blood: A dense fibrotic peri-tumoral stromal phenotype.
Derakhshandeh, R., Sanadhya, S., Han, K.L., Chen, H., Goloubeva, O., Webb, T.J., Younis, R.H., 2018. Oncotarget 9.
Circulating Semaphorin 4D as a Marker for Predicting Radiographic Progression in Patients with Rheumatoid Arthritis.
Ha, Y.-J., Han, D.W., Kim, J.H., Chung, S.W., Kang, E.H., Song, Y.W., Lee, Y.J., 2018. Dis. Markers 2018, 2318386.
PMID: 30538782; PMCID: PMC6261241
Promotion of Sema4D expression by tumor-associated macrophages: Significance in gastric carcinoma.
Li, H., Wang, J.-S., Mu, L.-J., Shan, K.-S., Li, L.-P., Zhou, Y.-B., 2018. World J. Gastroenterol. 24, 593–601.
PMID: 29434448; PMCID: PMC5799860
Semaphorin 4D correlates with increased bone resorption, hypercalcemia, and disease stage in newly diagnosed patients with multiple myeloma.
Terpos, E., Ntanasis-Stathopoulos, I., Christoulas, D., Bagratuni, T., Bakogeorgos, M., Gavriatopoulou, M., Eleutherakis-Papaiakovou, E., Kanellias, N., Kastritis, E., Dimopoulos, M.A., 2018. Blood Cancer J. 8, 42.
PMID: 29748532; PMCID: PMC5945651
Semaphorin 4D promotes bone invasion in head and neck squamous cell carcinoma.
Takada, H., Ibaragi, S., Eguchi, T., Okui, T., Obata, K., Masui, M., Morisawa, A., Takabatake, K., Kawai, H., Yoshioka, N., Hassan, N.M.M., Shimo, T., Hu, G.-F., Nagatsuka, H., Sasaki, A., 2017. Int. J. Oncol. 51, 625–632.
Recruitment of Tiam1 to Semaphorin 4D Activates Rac and Enhances Proliferation, Invasion, and Metastasis in Oral Squamous Cell Carcinoma.
Zhou, H., Kann, M.G., Mallory, E.K., Yang, Y.-H., Bugshan, A., Binmadi, N.O., Basile, J.R., 2017. Neoplasia N. Y. N 19, 65–74.
PMID: 28038319; PMCID: PMC5198113
The role of semaphorin 4D as a potential biomarker for antiangiogenic therapy in colorectal cancer.
Ding, X., Qiu, L., Zhang, L., Xi, J., Li, D., Huang, X., Zhao, Y., Wang, X., Sun, Q., 2016. OncoTargets Ther. 9, 1189–1204.
PMID: 27022279; PMCID: PMC4789851
Generation and preclinical characterization of an antibody specific for SEMA4D.
Fisher, T.L., Reilly, C.A., Winter, L.A., Pandina, T., Jonason, A., Scrivens, M., Balch, L., Bussler, H., Torno, S., Seils, J., Mueller, L., Huang, H., Klimatcheva, E., Howell, A., Kirk, R., Evans, E., Paris, M., Leonard, J.E., Smith, E.S., Zauderer, M., 2016. mAbs 8, 150–162.
The combined expression of Semaphorin4D and PlexinB1 predicts disease recurrence in colorectal cancer.
Ikeya, T., Maeda, K., Nagahara, H., Shibutani, M., Iseki, Y., Hirakawa, K., 2016. BMC Cancer 16.
PMID: 27456345; PMCID: PMC4960918
The role of semaphorin 4D in tumor development and angiogenesis in human breast cancer.
Jiang, H., Chen, C., Sun, Q., Wu, J., Qiu, L., Gao, C., Liu, W., Yang, J., Jun, N., Dong, J., 2016. OncoTargets Ther. 9, 5737–5750.
PMID: 27729799; PMCID: PMC5045906
Soluble SEMA4D/CD100: A novel immunoregulator in infectious and inflammatory diseases.
Maleki, K.T., Cornillet, M., Björkström, N.K., 2016. Clin. Immunol. 163, 52–59.
Safety, Pharmacokinetics, and Pharmacodynamics of a Humanized Anti-Semaphorin 4D Antibody, in a First-In-Human Study of Patients with Advanced Solid Tumors.
Patnaik, A., Weiss, G.J., Leonard, J.E., Rasco, D.W., Sachdev, J.C., Fisher, T.L., Winter, L.A., Reilly, C., Parker, R.B., Mutz, D., Blaydorn, L., Tolcher, A.W., Zauderer, M., Ramanathan, R.K., 2016. Clin. Cancer Res. 22, 827–836.
Semaphorin 4D Promotes Skeletal Metastasis in Breast Cancer.
Yang, Y.-H., Buhamrah, A., Schneider, A., Lin, Y.-L., Zhou, H., Bugshan, A., Basile, J.R., 2016a. PLOS ONE 11, e0150151.
Semaphorin 4D Promotes Skeletal Metastasis in Breast Cancer.
Yang, Y.-H., Buhamrah, A., Schneider, A., Lin, Y.-L., Zhou, H., Bugshan, A., Basile, J.R., 2016b. PLOS ONE 11, e0150151.
Antibody Blockade of Semaphorin 4D Promotes Immune Infiltration into Tumor and Enhances Response to Other Immunomodulatory Therapies.
Evans, E.E., Jonason, A.S., Bussler, H., Torno, S., Veeraraghavan, J., Reilly, C., Doherty, M.A., Seils, J., Winter, L.A., Mallow, C., Kirk, R., Howell, A., Giralico, S., Scrivens, M., Klimatcheva, K., Fisher, T.L., Bowers, W.J., Paris, M., Smith, E.S., Zauderer, M., 2015. Cancer Immunol. Res. 3, 689–701.
Reduced expression of semaphorin 4D and plexin-B in breast cancer is associated with poorer prognosis and the potential linkage with oestrogen receptor.
Malik, M.F.A., Ye, L., Jiang, W.G., 2015. Oncol. Rep. 34, 1049–1057.
A Sleeping Beauty forward genetic screen identifies new genes and pathways driving osteosarcoma development and metastasis.
Moriarity, B.S., Otto, G.M., Rahrmann, E.P., Rathe, S.K., Wolf, N.K., Weg, M.T., Manlove, L.A., LaRue, R.S., Temiz, N.A., Molyneux, S.D., Choi, K., Holly, K.J., Sarver, A.L., Scott, M.C., Forster, C.L., Modiano, J.F., Khanna, C., Hewitt, S.M., Khokha, R., Yang, Y., Gorlick, R., Dyer, M.A., Largaespada, D.A., 2015. Nat. Genet. 47, 615–624.
Semaphorin 4D and hypoxia-inducible factor-1α overexpression is related to prognosis in colorectal carcinoma.
Wang, J.-S., Jing, C.-Q., Shan, K.-S., Chen, Y.-Z., Guo, X.-B., Cao, Z.-X., Mu, L.-J., Peng, L.-P., Zhou, M.-L., Li, L.-P., 2015. World J. Gastroenterol. 21, 2191–2198.
Serum Soluble Semaphorin 4D is Associated with Left Atrial Diameter in Patients with Atrial Fibrillation.
Xiang, L., You, T., Chen, J., Xu, W., Jiao, Y., 2015. Med. Sci. Monit. Int. Med. J. Exp. Clin. Res. 21, 2912–2917.
PMID: 26417899; PMCID: PMC4596452
Semaphorin 4D Contributes to Rheumatoid Arthritis by Inducing Inflammatory Cytokine Production: Pathogenic and Therapeutic Implications: Sema4D IN RHEUMATOID ARTHRITIS.
Yoshida, Y., Ogata, A., Kang, S., Ebina, K., Shi, K., Nojima, S., Kimura, T., Ito, D., Morimoto, K., Nishide, M., Hosokawa, T., Hirano, T., Shima, Y., Narazaki, M., Tsuboi, H., Saeki, Y., Tomita, T., Tanaka, T., Kumanogoh, A., 2015. Arthritis Rheumatol. 67, 1481–1490.
Serum Sema4D levels are associated with lumbar spine bone mineral density and bone turnover markers in patients with postmenopausal osteoporosis.
Zhang, Yiyuan, Feng, E., Xu, Y., Wang, W., Zhang, T., Xiao, L., Chen, R., Lin, Yu, Chen, D., Lin, L., Chen, K., Lin, Yanbin, 2015. Int. J. Clin. Exp. Med. 8, 16352–16357
PMID: 26629156; PMCID: PMC4659044
Anabolic bone formation via a site-specific bone-targeting delivery system by interfering with semaphorin 4D expression.
Zhang, Yufeng, Wei, L., Miron, R.J., Shi, B., Bian, Z., 2015. J. Bone Miner. Res. Off. J. Am. Soc. Bone Miner. Res. 30, 286–296.
PMID: 25088728
Semaphorin 4D expression is associated with a poor clinical outcome in cervical cancer patients.
Liu, H., Yang, Y., Xiao, J., Yang, S., Liu, Y., Kang, W., Li, X., Zhang, F., 2014. Microvasc. Res. 93, 1–8.
The Semaphorin 4D-Plexin-B1-RhoA signaling axis recruits pericytes and regulates vascular permeability through endothelial production of PDGF-B and ANGPTL4.
Zhou, H., Yang, Y.-H., Basile, J.R., 2014. Angiogenesis 17, 261–274.
Ki-67 and CD100 immunohistochemical expression is associated with local recurrence and poor prognosis in soft tissue sarcomas, respectively.
Campos, M., De Campos, S.G.P., Ribeiro, G.G., Eguchi, F.C., Silva, S.R.M.D., De Oliveira, C.Z., Da Costa, A.M., Curcelli, E.C., Nunes, M.C., Penna, V., Longatto-Filho, A., 2013. Oncol. Lett. 5, 1527–1535.
Overexpression of Semaphorin4D Indicates Poor Prognosis and Prompts Monocyte Differentiation toward M2 Macrophages in Epithelial Ovarian Cancer.
Chen, Y., Zhang, L., Lv, R., Zhang, W.-Q., 2013. Asian Pac. J. Cancer Prev. 14, 5883–5890.
Function of mutant and wild-type plexinB1 in prostate cancer cells: PlexinB1 and Prostate Cancer.
Damola, A., Legendre, A., Ball, S., Masters, J.R., Williamson, M., 2013. The Prostate 73, 1326–1335.
Increased Levels of Plasma Soluble Sema4D in Patients with Heart Failure.
Lu, Q., Dong, N., Wang, Q., Yi, W., Wang, Y., Zhang, S., Gu, H., Zhao, X., Tang, X., Jin, B., Wu, Q., Brass, L.F., Zhu, L., 2013. PLoS ONE 8, e64265.
Over-Expression of Semaphorin4D, Hypoxia-Inducible Factor-1α; and Vascular Endothelial Growth Factor Is Related to Poor Prognosis in Ovarian Epithelial Cancer.
Chen, Y., Zhang, L., Pan, Y., Ren, X., Hao, Q., 2012. Int. J. Mol. Sci. 13, 13264–13274.
Neuropilins lock secreted semaphorins onto plexins in a ternary signaling complex.
Janssen, B.J.C., Malinauskas, T., Weir, G.A., Cader, M.Z., Siebold, C., Jones, E.Y., 2012. Nat. Struct. Mol. Biol. 19, 1293–1299.
Bone cell communication factors and Semaphorins.
Negishi-Koga, T., Takayanagi, H., 2012. BoneKEy Rep. 1, 183.
PMID: 24171101; PMCID: PMC3810552
Diverse roles for semaphorin-plexin signaling in the immune system.
Takamatsu, H., Kumanogoh, A., 2012. Trends Immunol. 33, 127–135.
PMID: 22325954
Peripheral blood lymphocytes analysis detects CD100/SEMA4D alteration in systemic sclerosis patients.
Besliu, A., Banica, L., Predeteanu, D., Vlad, V., Ionescu, R., Pistol, G., Opris, D., Berghea, F., Stefanescu, M., Matache, C., 2011. Autoimmunity 44, 427–436.
Semaphorin 4D, a lymphocyte semaphorin, enhances tumor cell motility through binding its receptor, plexinB1, in pancreatic cancer.
Kato, S., Kubota, K., Shimamura, T., Shinohara, Y., Kobayashi, N., Watanabe, S., Yoneda, M., Inamori, M., Nakamura, F., Ishiguro, H., Nakaigawa, N., Nagashima, Y., Taguri, M., Kubota, Y., Goshima, Y., Morita, S., Endo, I., Maeda, S., Nakajima, A., Nakagama, H., 2011. Cancer Sci. 102, 2029–2037.
Suppression of bone formation by osteoclastic expression of semaphorin 4D.
Negishi-Koga, T., Shinohara, M., Komatsu, N., Bito, H., Kodama, T., Friedel, R.H., Takayanagi, H., 2011a. Nat. Med. 17, 1473–1480.
Suppression of bone formation by osteoclastic expression of semaphorin 4D.
Negishi-Koga, T., Shinohara, M., Komatsu, N., Bito, H., Kodama, T., Friedel, R.H., Takayanagi, H., 2011b. Nat. Med. 17, 1473–1480.
Biology and function of neuroimmune semaphorins 4A and 4D.
Nkyimbeng-Takwi, E., Chapoval, S.P., 2011. Immunol. Res. 50, 10–21.
PMID: 21203905; PMCID: PMC3366695
Roles of Sema4D and Plexin-B1 in tumor progression.
Ch’ng, E.S., Kumanogoh, A., 2010. Mol. Cancer 9, 251.
Proteolytic and non-proteolytic roles of membrane type-1 matrix metalloproteinase in malignancy.
Strongin, A.Y., 2010. Biochim. Biophys. Acta 1803, 133–141.
PMID: 19406172; PMCID: PMC2823998
ADAM17 as a Therapeutic Target in Multiple Diseases.
Arribas, J., Esselens, C., 2009. Curr. Pharm. Des. 15, 2319–2335.
Semaphorin signaling in cancer cells and in cells of the tumor microenvironment - two sides of a coin.
Capparuccia, L., Tamagnone, L., 2009. J. Cell Sci. 122, 1723–1736.
Semaphorins and their receptors in immune cell interactions.
Suzuki, K., Kumanogoh, A., Kikutani, H., 2008. Nat. Immunol. 9, 17–23.
MT1-MMP Controls Tumor-induced Angiogenesis through the Release of Semaphorin 4D.
Basile, J.R., Holmbeck, K., Bugge, T.H., Gutkind, J.S., 2007. J. Biol. Chem. 282, 6899–6905.
Semaphorin 4D provides a link between axon guidance processes and tumor-induced angiogenesis.
Basile, J.R., Castilho, R.M., Williams, V.P., Gutkind, J.S., 2006. Proc. Natl. Acad. Sci. 103, 9017–9022.
The semaphorins.
Yazdani, U., Terman, J.R., 2006. Genome Biol. 7, 211.
PMID: 16584533; PMCID: PMC1557745
Sema4D induces angiogenesis through Met recruitment by Plexin B1.
Conrotto, P., 2005. Blood 105, 4321–4329.
Sema4D induces angiogenesis through Met recruitment by Plexin B1.
Conrotto, P., Valdembri, D., Corso, S., Serini, G., Tamagnone, L., Comoglio, P.M., Bussolino, F., Giordano, S., 2005. Blood 105, 4321–4329.
PMID: 15632204
Semaphorins command cells to move.
Kruger, R.P., Aurandt, J., Guan, K.-L., 2005. Nat. Rev. Mol. Cell Biol. 6, 789–800.
PMID: 16314868
Class IV Semaphorins Promote Angiogenesis by Stimulating Rho-Initiated Pathways through Plexin-B.
Basile, J.R., Barac, A., Zhu, T., Guan, K.-L., Gutkind, J.S., 2004. Cancer Res. 64, 5212–5224.
Biological Activity of Soluble CD100. II. Soluble CD100, Similarly to H-SemaIII, Inhibits Immune Cell Migration.
Delaire, S., Billard, C., Tordjman, R., Chedotal, A., Elhabazi, A., Bensussan, A., Boumsell, L., 2001. J. Immunol. 166, 4348–4354.
Plexins Are a Large Family of Receptors for Transmembrane, Secreted, and GPI-Anchored Semaphorins in Vertebrates.
Tamagnone, L., Artigiani, S., Chen, H., He, Z., Ming, G., Song, H., Chedotal, A., Winberg, M.L., Goodman, C.S., Poo, M., Tessier-Lavigne, M., Comoglio, P.M., n.d. 10
PMID: 10520995
All Biomedica ELISAs are validated according to international FDA/ICH/EMEA guidelines. For more information about our validation guidelines, please refer to our quality (->link) page and published validation guidelines and literature.
1. ICH Q2(R1) Validation of Analytical Procedures: Text and Methodology
2. EMEA/CHMP/EWP/192217/2009 Guideline on bioanalytical method validation
3. Bioanalytical Method Validation, Guidance for Industry, FDA, May 2018
Calibration
The soluble Semaphorin 4D immunoassay is calibrated against recombinant soluble Semaphorin 4D protein (AA22-734 of Q92854 (Uniprot ID)).
Detection Limit & Sensitivity
To determine the sensitivity of the soluble Semaphorin 4D ELISA, experiments measuring the lower limit of detection (LOD) and the lower limit of quantification (LLOQ) were conducted.
The LOD, also called the detection limit, is the lowest point at which a signal can be distinguished above the background signal, i.e. the signal that is measured in the absence of soluble Semaphorin 4D, with a confidence level of 99%. It is defined as the mean back calculated concentration of standard 1 (0 pmol/l of soluble Semaphorin 4D) plus three times the standard deviation of the measurements.
The LLOQ, or sensitivity of an assay, is the lowest concentration at which an analyte can be accurately quantified. The criteria for accurate quantification at the LLOQ are an analyte recovery between 75 and 125% and a coefficient of variation (CV) of less than 25%. To determine the LLOQ, standard 2, i.e. the lowest standards containing soluble Semaphorin 4D, is diluted, measured and its concentration back calculated. The lowest dilution, which meets both criteria, is reported as the LLOQ.
The following values were determined for the soluble Semaphorin 4D ELISA:
LOD |
12 pmol/l |
LLOQ |
31 pmol/l |
Precision
The precision of an ELISA is defined as its ability to measure the same concentration consistently within the same experiments carried out by one operator (within-run precision or repeatability) and across several experiments using the same samples but conducted by several operators at different locations using different ELISA lots (in-between-run precision or reproducibility).
Within-Run Precision
Within-run precision was tested by measuring the same samples five times within one soluble Semaphorin 4D ELISA lot. The experiment was conducted by one operator.
ID |
Within-Run Precision |
Mean sSEMA4D [pmol/l] |
SD [pmol/l] |
CV (%) |
Sample 1 |
5 | 126 | 10.4 | 8 |
Sample 2 |
5 | 1,003 | 63.8 | 6 |
In-Between-Run Precision
In-between-run precision was assessed by measuring the same samples eleven times within two soluble Semaphorin 4D ELISA lots. The measurements were carried out by four different operators.
ID |
In-Between Run Precision |
Mean sSEMA4D [pmol/l] |
SD [pmol/l] |
CV (%) |
Sample 1 |
11 | 134 | 14.4 | 11 |
Sample 2 |
11 | 1,012 | 55.1 | 5 |
Accuracy
The accuracy of an ELISA is defined as the precision with which it can recover samples of known concentrations.
The recovery of the soluble Semaphorin 4D ELISA was measured by adding recombinant soluble Semaphorin 4D to human samples containing a known concentration endogenous soluble Semaphorin 4D. The % recovery of the spiked concentration was calculated as the percentage of measured compared over the expected value.
This table shows the summary of the recovery experiments in the soluble Semaphorin 4D ELISA in different sample matrices:
|
% Recovery |
||||
Sample Matrix |
n |
+200 pmol/l |
+1,000 pmol/l |
||
Mean |
Range |
Mean |
Range |
||
EDTA plasma |
6 |
116 |
102 – 136 |
92 |
79 - 104 |
Citrate plasma |
2 |
94 |
82 – 106 |
109 |
103 - 114 |
Heparin plasma |
2 |
79 |
78 - 80 |
83 |
82 - 83 |
Data showing recovery of recombinant soluble Semaphorin 4D in human EDTA plasma samples:
sSEMA4D [pmol/l] |
% Recovery |
|||||
Sample Matrix |
ID |
Reference |
+ 200 pmol/l |
+ 1000 pmol/l |
+ 200 pmol/l |
+ 1000 pmol/l |
EDTA plasma |
e1 |
323 | 527 | 1,367 | 102 | 104 |
EDTA plasma |
e2 |
244 | 480 | 1,032 | 118 | 79 |
EDTA plasma |
e3 |
337 | 608 | 1,208 | 136 | 87 |
EDTA plasma |
e4 |
378 | 634 | 1,360 | 128 | 98 |
EDTA plasma |
e5 |
413 | 626 | 1,322 | 106 | 91 |
EDTA plasma |
e6 |
261 | 469 | 1,175 | 104 | 91 |
Mean |
116 | 92 | ||||
|
|
|
|
Min |
102 | 79 |
|
|
|
|
Max |
136 | 104 |
Data showing recovery of recombinant soluble Semaphorin 4D in a human citrate plasma sample:
sSEMA4D [pmol/l] |
% Recovery |
|||||
Sample Matrix |
ID |
Reference |
+ 200 pmol/l |
+ 1000 pmol/l |
+ 200 pmol/l |
+ 1000 pmol/l |
Citrate plasma |
c1 | 258 | 470 | 1,399 | 106 | 114 |
Citrate plasma |
c2 | 356 | 520 | 1,387 | 82 | 103 |
Data showing recovery of soluble Semaphorin 4D in human heparin plasma samples:
sSEMA4D [pmol/l] |
% Recovery |
|||||
Sample Matrix |
ID |
Reference |
+ 200 pmol/l |
+ 1000 pmol/l |
+ 200 pmol/l |
+ 1000 pmol/l |
Heparin plasma |
h1 |
297 | 458 | 1,117 | 80 | 82 |
Heparin plasma |
h2 |
314 |
469 |
1,144 |
78 |
83 |
Dilution Linearity & Parallelism
Tests of dilution linearity and parallelism ensure that both endogenous and recombinant samples containing soluble Semaphorin 4D behave in a dose dependent manner and are not affected by matrix effects. Dilution linearity assesses the accuracy of measurements in diluted human samples spiked with known concentrations of recombinant analyte. By contrast, parallelism refers to dilution linearity in human samples and provides evidence that the endogenous analyte behaves the same way as the recombinant one. Dilution linearity and parallelism are assessed for each sample type and are considered acceptable if the results are within ± 20% of the expected concentration.
Dilution linearity was assessed by serially diluting human samples spiked with 1,000 pmol/l recombinant soluble Semaphorin 4D with standard 1 (human plasma, containing no soluble Semaphorin 4D).
The table below shows the mean recovery and range of serially diluted recombinant soluble Semaphorin 4D in EDTA plasma:
|
|
|
% Recovery of recombinant sSEMA4D in diluted samples |
|||||||
Sample Matrix |
n |
1+1 |
1+3 |
1+7 |
1+15 |
|||||
Mean |
Range |
Mean |
Range |
Mean |
Range |
Mean |
Range |
|||
EDTA plasma |
6 |
103 | 87-118 | 106 | 83-124 | 82 | 56-102 | 94 | 80-114 |
Data showing dilution linearity of 1,000 pmol/l recombinant soluble Semaphorin 4D spiked into human EDTA plasma samples (reference) containing endogenous soluble Semaphorin 4D:
sSEMA4D [pmol/l] | % Recovery | |||||||||
Sample Matrix | ID | Reference + 1,000 pmol/l | 1+1 | 1+3 | 1+7 | 1+15 | 1+1 | 1+3 | 1+7 | 1+15 |
EDTA plasma | e1 | 1,311 | 678 | 272 | 91 | 71 | 103 | 83 | 56 | 86 |
EDTA plasma | e2 | 971 | 525 | 279 | 98 | 69 | 108 | 115 | 81 | 114 |
EDTA plasma | e3 | 1,124 | 546 | 297 | 103 | 56 | 97 | 106 | 73 | 80 |
EDTA plasma | e4 | 1,15 | 603 | 310 | 137 | 63 | 105 | 108 | 95 | 88 |
EDTA plasma | e5 | 1,159 | 502 | 293 | 148 | 64 | 87 | 101 | 102 | 88 |
EDTA plasma | e6 | 1,122 | 663 | 349 | 119 | 75 | 118 | 124 | 85 | 107 |
Mean | 103 | 106 | 82 | 94 | ||||||
Min | 87 | 83 | 56 | 80 | ||||||
Max | 118 | 124 | 102 | 114 |
Parallelism was assessed by serially diluting human samples containing endogenous soluble Semaphorin 4D with standard 1 (human plasma containing no soluble Semaphorin 4D).
The table below shows the mean recovery and range of serially diluted endogenous soluble Semaphorin 4D in several sample matrices:
% Recovery of endogenous sSEMA4D in diluted samples | |||||||
Sample Matrix | n | 1+1 | 1+3 | 1+7 | |||
Mean | Range | Mean | Range | Mean | Range | ||
EDTA plasma | 4 | 106 | 93 – 126 | 92 | 89 – 106 | 99 | 90 - 105 |
Citrate plasma | 2 | 111 | 109 – 112 | 109 | 104 – 114 | 121 | 119 - 124 |
Heparin plasma | 2 | 103 | 98 – 107 | 93 | 77 – 110 | 133 | 89 - 177 |
Data showing recovery of endogenous soluble Semaphorin 4D in human EDTA plasma samples:
sSEMA4D [pmol/l] |
% Recovery |
|||||||
Sample matrix |
ID |
Reference |
1+1 |
1+3 |
1+7 |
1+1 |
1+3 |
1+7 |
EDTA plasma | e1 | 789 | 425 | 210 | 104 | 108 | 106 | 105 |
EDTA plasma | e2 | 967 | 608 | 200 | 126 | 126 | 83 | 104 |
EDTA plasma | e3 | 1,106 | 515 | 252 | 133 | 93 | 91 | 97 |
EDTA plasma | e4 | 976 | 471 | 217 | 109 | 96 | 89 | 90 |
Mean | 106 | 92 | 99 |
Data showing recovery of endogenous soluble Semaphorin 4D in human citrate plasma samples:
sSEMA4D [pmol/l] |
% Recovery |
|||||||
Sample matrix |
ID |
Reference |
1+1 |
1+3 |
1+7 |
1+1 |
1+3 |
1+7 |
Citrate plasma | c1 | 274 | 153 | 78 | 41 | 112 | 114 | 119 |
Citrate plasma | c2 | 272 | 148 | 70 | 42 | 109 | 104 | 124 |
Data showing recovery of endogenous soluble Semaphorin 4D in a human heparin plasma sample:
sSEMA4D [pmol/l] |
% Recovery |
|||||||
Sample matrix |
ID |
Reference |
1+1 |
1+3 |
1+7 |
1+1 |
1+3 |
1+7 |
Heparin plasma | h1 | 403 | 197 | 77 | 45 | 98 | 77 | 89 |
Heparin plasma | h2 | 326 | 175 | 90 | 72 | 107 | 110 | 177 |
Specificity
The specificity of an ELISA is defined as its ability to exclusively recognize an analyte, which means that the ELISA antibodies will bind to the target analyte while not binding to other molecules in solution.
To characterize the antibody pair, both the capture and the detection antibodies were characterized through epitope mapping and affinity measurements. In addition, the specificity of the ELISA was established through competition experiments, which measure the ability of the antibodies to exclusively bind soluble Semaphorin 4D
Epitope Mapping
Antibody binding sites were determined by epitope mapping using microarray analysis (Pepperprint GmbH).
The monoclonal capture antibody was determined to bind to AA30-AA34.
The bivalent Fab bacterial alkaline phosphatase fusion antibody-HRP binds to region AA 238-241.
Isoforms
Isoform 1 and 2 are identical between AA 1-554. The epitopes of the antibodies utilized in this ELISA are situated in this area.
Competition of Signal
Competition experiments were carried out by pre-incubating human samples with a ten-fold excess of coating antibody. The concentration measured in this mixture was then compared to a reference value, which was obtained from the same sample but without the pre-incubation step. Mean competition was 98%.
sSEMA4D [pmol/l] | %Competition | |||
Sample matrix | ID | Reference | Reference+ antibody | |
EDTA plasma | e1 | 926 | 3 | 100 |
EDTA plasma | e2 | 761 | 3 | 100 |
EDTA plasma | e3 | 790 | 3 | 100 |
EDTA plasma | e4 | 323 | 0 | 100 |
EDTA plasma | e5 | 244 | 0 | 100 |
EDTA plasma | e6 | 401 | 0 | 100 |
EDTA plasma | e7 | 337 | 0 | 100 |
EDTA plasma | e8 | 378 | 0 | 100 |
EDTA plasma | e9 | 424 | 45 | 89 |
EDTA plasma | e10 | 413 | 38 | 91 |
EDTA plasma | e11 | 261 | 5 | 98 |
Citrate plasma | c1 | 269 | 0 | 100 |
Citrate plasma | c2 | 384 | 2 | 99 |
Citrate plasma | c3 | 302 | 4 | 99 |
Heparin plasma | h1 | 307 | 1 | 100 |
Heparin plasma | h2 | 281 | 3 | 99 |
Mean | 98 |
Sample Stability
The stability of endogenous soluble Semaphorin 4D was tested by comparing soluble Semaphorin 4D measurements in samples that had undergone up to four freeze-thaw cycles.
For freeze-thaw experiments, samples were collected according to the supplier’s instruction using blood collection devices and stored at -80°C. Reference samples were freeze-thawed once. The mean recovery of sample concentration after four freeze-thaw cycles is 100%.
sSEMA4D [pmol/l] | % Recovery after 4 freeze/thaw cycles | |||||
Sample matrix | ID | Reference | 2x | 3x | 4x | |
EDTA plasma | e1 | 351 | 340 | 336 | 366 | 96 |
EDTA plasma | e2 | 372 | 356 | 327 | 351 | 106 |
Citrate plasma | c1 | 343 | 358 | 314 | 345 | 99 |
Citrate plasma | c2 | 410 | 468 | 454 | 429 | 96 |
Heparin plasma | h1 | 287 | 270 | 280 | 282 | 102 |
Heparin plasma | h2 | 261 | 252 | 269 | 250 | 105 |
Mean | 100 |
All samples should undergo a maximum of four freeze-thaw cycles.
Sample Values
Soluble Semaphorin 4D Values in Apparently Healthy Individuals
To provide expected values for circulating soluble Semaphorin 4D, a panel of samples from apparently healthy donors was tested.
A summary of the results is shown below:
sSEMA4D [pmol/l] | |||||||
Sample Matrix |
n | Mean | Median | 5% Percentile | 95% Percentile | Minimum | Maximum |
EDTA plasma |
44 | 239 | 245 | 119 | 344 | 113 | 357 |
Heparin plasma |
28 | 194 | 201 | 112 | 270 | 109 | 276 |
Citrate plasma |
43 | 199 | 192 | 130 | 303 | 125 | 355 |
It is recommended to establish the normal range for each laboratory.
The figure below shows a comparison of sample values in different sample matrices.
Soluble Semaphorin 4D Values in an Unselected Hospital Panel
In addition to samples from apparently healthy donors, a panel of samples from unselected hospital patients was tested.
A summary of the results is shown below:
sSEMA4D [pmol/l] | |||||||
Sample Matrix |
n | Mean | Median | 5% Percentile | 95% Percentile | Minimum | Maximum |
EDTA plasma |
4 | 997 | 991 | 841 | 1165 | 841 | 1,165 |
Heparin plasma |
13 | 274 | 268 | 199 | 330 | 199 | 330 |
Citrate plasma |
7 | 412 | 417 | 326 | 477 | 326 | 477 |
A comparison of EDTA plasma samples from an apparently healthy individuals and from an unselected hospital patient cohort shows that soluble Semaphorin 4D is significantly increased in the hospitalized cohort:
sSEMA4D [pmol/l] | |||||||
Panel |
n | Mean | Median | 5% Percentile | 95% Percentile | Minimum | Maximum |
Unselected hospital |
4 | 997 | 991 | 841 | 1165 | 841 | 1,165 |
Apparenly healthy |
44 | 239 | 245 | 119 | 344 | 113 | 357 |
Matrix Comparison
To assess whether all tested matrices behave the same way in the soluble Semaphorin 4D ELISA, concentrations of soluble Semaphorin 4D were measured in EDTA, heparin and citrate plasma samples prepared from apparently healthy donor. Each individual donated blood in all tested sample matrices.
Soluble Semaphorin 4D was measured in plasma samples from seven different individual donors. A summary table of soluble Semaphorin 4D levels in various sample matrices is shown below:
|
sSEMA4D [pmol/l] | |||
Donor ID | EDTA plasma | Citrate plasma | Heparin plasma | % CV |
#1 | 244 | 239 | 250 | 2 |
#2 | 156 | 213 | 204 | 13 |
#3 | 192 | 237 | 237 | 9 |
#4 | 177 | 184 | 182 | 2 |
#5 | 347 | 325 | 266 | 11 |
#6 | 188 | 262 | 211 | 14 |
#7 | 169 | 148 | 171 | 6 |
Mean | 8 |
A figure of soluble Semaphorin 4D levels in various sample matrices is shown below:
Why we don’t recommend serum as matrix to measure soluble Semaphorin 4D?
We analyzed soluble SEMA4D in both serum and plasma samples. Based on our results we do not recommend the use of serum as matrix for sSEMA4D analysis. A comparison between sSEMA4D levels in serum and plasma resulted in significantly elevated sSEMA4D levels in serum. This can be explained that plasma anticoagulants prohibit coagulation-induced platelet activation that might lead to sSEMA4D shedding. Zhu L and colleagues (Blood, 2013; 16;121(20):4221–4230) demonstrated that blood coagulation-related platelet activation, e.g. due to vascular injury during sample collection, leads to increased sSEMA4D surface expression, followed by shedding into the circulation. We could demonstrate that plasma is free of shed sSEMA4D and is a suitable matrix for reproducible quantification of soluble Semaphorin 4D (Laber A et al., Analytical Biochemistry, 2019; in press).