KR20230042682A - Marker for cervical insufficiency - Google Patents

Abstract

The present invention relates to a marker for incompetent cervix. The marker for incompetent cervix comprises an agent for measuring transcription levels of one or more genes selected from DEFA3, CD177, JUN, ELANE, BPI, MMP8, CEACAM8, CA1, HBA1, SLC4A1, ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CEACAM6, PGLYRP1, CHST13, CITED4, CFAP45, OSBPL1A, SIGLEC8, ALOX15, and IDH3A. According to the present invention, the health of a mother and a fetus can be improved.

Description

Marker for cervical insufficiency}

The present invention relates to markers capable of diagnosing cervical incompetence and prognosis after cervical ablation, and their use.

Preterm birth (PTB), defined as delivery before 37 weeks of gestation, occurs in more than 1 in 10 babies, and causes approximately one million child deaths each year from complications related to preterm birth [1]. Moreover, preterm birth is a major burden on the health care system due to long-term morbidity, such as neurodevelopmental disorders, as well as immediate complications of prematurity related to organ system immaturity [2-4]. One factor leading to preterm birth is cervical insufficiency (CI), characterized by spontaneous dilatation and disappearance of the cervix without painful contractions in the second trimester, accompanied by swelling of the fetal membranes, and premature rupture of the fetal membranes. and ultimately leads to the birth of an immature fetus [5]. Cervical incompetence accounts for approximately 0.5% to 1% of all pregnancies, and is associated with 2% to 15% of preterm births in the second trimester or 5% to 15% of extremely preterm births (<28 weeks) [6, 7]. Cervical manipulation surgery (e.g. loop electrosurgical resection, dilatation and curettage, cold-knife conization, hysteroscopy), cervical lacerations or obstetric injuries, collagen disorders (e.g. Ehlers-Danlos) and uterus Several factors, such as my exposure to diethylstilbestrol, are associated with cervical incompetence, and the cause is unknown [8]. Thus, cervical incompetence is diagnosed on the basis of either the classical past obstetric history (consecutive miscarriage occurring in the second or early third trimester without preceding uterine contractions) or a combination of obstetric history and cervical length measurement (Roman et al. al., 2016). Moreover, no laboratory tests or useful biomarkers for the diagnosis or prediction of cervical incompetence have been commercially available. Cervical ablation is a treatment for patients with cervical incompetence. However, guidelines for determining whether or not to perform cervical ablation are different, and even postoperative guidelines are different, and there are limitations in predicting pregnancy outcomes [9].

Korean Patent No. 1978401 (Announced on May 15, 2019) "Marker for diagnosis of cervical incompetence and its use"

Liu L. et al., The Lancet Global health 2019, 7(6):e721-e734 Iams JD, The New England journal of medicine 2014, 370(3):254-261 Mwaniki MK et al., Lancet (London, England) 2012, 379(9814):445-452 Murray CJ et al., Lancet (London, England) 2012, 380(9859):2197-2223 Vink J et al., Seminars in fetal & neonatal medicine 2016, 21(2):106-112 Mann EC et al., American journal of obstetrics and gynecology 1961, 81:209-222 Stromme WB et al., American journal of obstetrics and gynecology 1963, 85:223-233 Thakur M, Mahajan K: Cervical Incompetence. In: StatPearls. Treasure Island (FL): StatPearls Publishing Copyright ⓒ 2020, StatPearls Publishing LLC.; 2020 ACOG Practice Bulletin No.142: Cerclage for the management of cervical insufficiency. Obstetrics and gynecology 2014, 123(2 Pt 1):372-379 Kukurba KR, Montgomery SB: RNA Sequencing and Analysis. Cold Spring Harbor protocols 2015, 2015(11):951-969 Wang Z et al., Nature reviews Genetics 2009, 10(1):57-63 Nagalakshmi U et al., RNA-Seq: a method for comprehensive transcriptome analysis. Current protocols in molecular biology 2010, Chapter 4: Unit 4.11.11-13 Jiang H et al., BMC bioinformatics 2014, 15:182 Dobin A et al., Bioinformatics (Oxford, England) 2013, 29(1):15-21 Trapnell C et al., Nature biotechnology 2010, 28(5):511-515 Cullum R et al., Respirology (Carlton, Vic) 2011, 16(2):210-222 Reimand J, Arak T, Adler P, Kolberg L, Reisberg S, Peterson H, Vilo J: g:Profiler-a web server for functional interpretation of gene lists (2016 update). 2016, 44(W1):W83-89 Hein M et al., American journal of obstetrics and gynecology 2001, 185(3):586-592 Kawana K et al., Infection and immunity 2008, 76(7):3011-3018 Borregaard N et al., Trends in immunology 2007, 28(8):340-345 Stock AJ, Kasus-Jacobi A, Pereira HA: The role of neutrophil granule proteins in neuroinflammation and Alzheimer's disease. 2018, 15(1):240. Selsted ME et al., The Journal of clinical investigation 1985, 76(4):1436-1439 Aldred PM et al., Human molecular genetics 2005, 14(14):2045-2052 Prasad SV, Fiedoruk K: Expression and Function of Host Defense Peptides at Inflammation Sites. 2019, 21(1). Heine RP et al., Clinical infectious diseases: an official publication of the Infectious Diseases Society of America 1998, 27(3):513-518 Lee SE et al., American journal of obstetrics and gynecology 2008, 198(6):633.e631-638 Canny G et al., Proceedings of the National Academy of Sciences of the United States of America 2002, 99(6): 3902-3907 Biggio JR et al., American journal of obstetrics and gynecology 2005, 192(1):109-113 Son GH et al., American journal of reproductive immunology (New York, NY : 1989) 2016, 75(2):155-161 Wehkamp J et al., Proceedings of the National Academy of Sciences of the United States of America 2005, 102(50):18129-18134 Bryce J et al., Lancet (London, England) 2005, 365(9465):1147-1152

Therefore, the present invention aims to discover biomarkers for cervical incompetence, provide a composition, diagnostic kit, and diagnostic method for diagnosing cervical incompetence using the same, and also to select targets for treating cervical incompetence. do it with

We identified gene expression profiles and biological pathways associated with cervical insufficiency (CI) to explore potential biomarkers or therapeutic targets for CI. RNA sequencing (RNA-Seq) is a technology enabling comprehensive transcriptome analysis of genomes [10-12]. Compared to microarrays, RNA sequencing enables unbiased, probe-independent examination of gene expression data. We identified distinct gene expression profiles in CI by comparing the transcriptome profiles of CI patients with those of normal controls using RNA sequencing. In addition, we investigated whether genes were differentially expressed according to pregnancy outcomes in CI patients.

We performed whole blood RNA-Seq in patients with CI and compared the transcriptome profile to that of normal controls. As a result, it was confirmed that genes related to neutrophil activation and neutrophil-mediated immunity were upregulated in the CI group compared to the control group. The cervix is located between the vagina, which has a rich vaginal microbial environment, and the presumed sterile intrauterine space. Thus, the cervix remains closed until childbirth and contains immune cells (dendritic cells, neutrophils, and macrophages) and receptors for pattern recognition receptors, Toll-like receptors, advanced glycation end products, cytokines and chemokines, damage-associated molecular patterns, and antimicrobial peptides. It functions as a mechanical barrier against the rise of infection by maintaining an immunological barrier with molecular components including [18, 19]. Thus, women with disruption of the cervical barrier, such as with advanced cervical dilatation, have an increased risk of microbial invasion into the amnion. In CI patients with clinical symptoms such as cervical dilatation identified in the present invention, upregulated neutrophil immunity-related genes seem to protect the fetus, possibly by preventing the rise of infection. Neutrophils are specialized innate phagocytic cells densely packed into granules, which contain several proteins with a broad spectrum of antibacterial activity, divided into primary (azrophil), secondary (specific), gelatinase and secretory granules [20, 21 ]. Granules are heterogeneous in structure, content and function and can be readily released to participate in the host response to infection or inflammation. In this study, we identified a wide range of neutrophil-associated genes that were expressed at significantly higher levels in women with CI than in controls. Alpha dispensin expressed as azurophil granules is an antibacterial peptide with remarkable antibacterial, antifungal and antiviral activity against various microorganisms, implying its role in innate immunity, and also plays an important role in regulating the immune response [ 22-24]. A previous study reported that maternal plasma defensin levels were increased in women with histological chorioamnionitis after premature membrane rupture [25]. Therefore, the up-regulation of DEFA3 expression in maternal blood of the CI group observed in this study can be explained by intra-amniotic inflammation found in 80% of CI patients [26].

Bactericidal/permeability-increasing protein (BPI), a lipopolysaccharide-binding protein with bactericidal activity against Gram-negative organisms, neutralizes the inflammatory response induced by lipopolysaccharide, enhances phagocytosis regulation, and exhibits antifungal properties [27]. Considering the overexpression of DEFA3 as well as a wide range of neutrophil granule-related genes (ELANE, BPI, MMP8, CRISP3 and CEACAM8) in the CI group, vaginal microbial infection rises after cervical barrier disruption, leading to intrauterine inflammation/infection and maternal systemic inflammatory response. and neutrophil activation. Alpha-defensins and MMP8 have previously been proposed as biomarkers of preterm birth (PTB) due to their higher than live birth concentrations in the amniotic fluid of preterm mothers [25, 28]. However, there was no information about alpha-defensin and MMP8 expression in CI. Our results showed that the serum concentration of alpha-defensin 3 in the CI group was significantly higher than that in the control group. Thus, alpha-defensin 3 could be a biomarker for CI.

In addition, we confirmed that genes related to myeloid leukocyte activation and neutrophil-mediated immunity were upregulated in the CI group compared to the control group, resulting in systemic and intrauterine inflammation in CI patients. Intrauterine inflammation may be associated with CI, and its severity is associated with preterm birth in patients with CI [29]. Our results showed higher rates in the CI-preterm (CI-preterm; preterm delivery after cervical ablation for CI) group than in the CI-term (CI-term; delivery at normal term after cervical ablation for CI) group. Neutrophil counts were shown to indicate more severe inflammation. Since alpha-defensin is produced by neutrophils, the concentration of alpha-defensin 3 was expected to be higher in the CI-preterm delivery group than in the CI-term delivery group. However, our results showed that the concentration of alpha-defensin 3 tended to be higher in the CI-term delivery group. This trend was also shown in RNA sequencing and qRT-PCR results. DEFA3 expression was higher in the CI-term delivery group than the CI-preterm delivery group. The following can be inferred from these results. Alpha-defensins are stored in azurophil granules of neutrophils, but the granules are normally secretion-limited and are released into the extracellular milieu through degranulation of activated neutrophils. Also, alpha-defensins can be released after apoptosis, necrosis or NET-injury of neutrophils. Therefore, it can be considered that the expression level of alpha-defensin is not proportional to the number of neutrophils, but more related to the degree of activation of neutrophils. Alpha-defensins can modulate inflammation by inhibiting the biosynthesis of pro-inflammatory cytokines in macrophages. In a similar vein, our results showed that upregulated expression of various host defense-related genes, such as DEFA3, was associated with favorable pregnancy outcomes in CI patients.

Infections mainly caused by malaria, HIV, and parasites are known to be major causes of preterm birth worldwide [31]. Consistent with this, we found that the malaria and African trypanosomiasis pathways are enriched in the genes of the CI group. These findings indicate that there are many underestimated infections in CI that have not been identified in traditional microbial cultures, and that current culture techniques are extremely limited as diagnostic tests for amniotic fluid and systemic level infections. Moreover, the pathways identified as enriched in pregnancy maintenance genes were the NOD-like receptor and RIG-I-like receptor signaling pathways involved in the innate immune response. Our findings thus suggest that the immune response at the maternal-fetal interface and systemic level plays an important role in prolonging pregnancy by regulating the inflammatory response and preventing CI infection.

To the best of our knowledge, this is the first RNA-seq study of whole blood from patients with CI. To date, there have been few high-throughput studies of CI, because isolated CI is a relatively rare condition and there are no objective diagnostic criteria, making it difficult to determine whether subjects should be included or not, and it is difficult to analyze cervical tissue during pregnancy. In the present study, only women with cervical dilatation were included, excluding women with short cervix in ultrasound examination. The presence of symptoms such as uterine contraction or vaginal bleeding was closely monitored in the CI group, and patients with suspected symptoms were excluded from the study group. In addition, although the pathophysiology or pathogenesis of CI could not be investigated using cervical tissue, the present invention revealed a unique transcriptome profile for cervical barrier disruption and differential gene expression according to pregnancy outcomes. The sample size in our study was small, especially in the control group. However, we carefully matched the maternal and gestational ages of CI and control women and were able to overcome the limitations of the small sample size through homologous gene expression in normal controls.

In conclusion, we identified potential differences in gene expression between CI and control groups, indicating upregulation of genes related to neutrophil activation and neutrophil-mediated immunity in the CI group compared to the control group. Moreover, immune and defense responses to organism-specific genes and immune response signaling pathways are likely related to pregnancy outcomes in CI patients.

DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit alpha 1), SLC4A1 (solute carrier family 4 member) 1), ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CRISP3, CEACAM6, PGLYRP1, CHST13, CITED4, CFAP45, OSBPL1A, SIGLEC8, ALOX15, and IDH3A. It relates to a composition for diagnosing cervical incompetence comprising an agent for measuring the level.

In addition, the present invention is DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit alpha 1), SLC4A1 (solute carrier family) 4 member 1), ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CRISP3, CEACAM6, PGLYRP1, CHST13, CITED4, CFAP45, OSBPL1A, SIGLEC8, ALOX15 and IDH3A It relates to a composition for diagnosing cervical incompetence comprising an agent for measuring the expression level of at least one protein.

In addition, the present invention is DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit alpha 1), SLC4A1 (solute carrier family) 4 member 1), ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CRISP3, CEACAM6, PGLYRP1, CHST13, CITED4, and the transcription level of one or more genes selected from CFAP45, or generated from these genes It relates to a composition for diagnosing cervical incompetence, which is judged as cervical incompetence when the protein expression level is increased compared to a normal control group.

In addition, the present invention is OSBPL1A, SIGLEC8, ALOX15 and IDH3A in the case where the transcription level of one or more genes selected from or the protein expression level produced from this gene is reduced compared to the normal control group, the composition for diagnosing cervical incompetence, which is judged as cervical incompetence it's about

In addition, the present invention relates to a composition for diagnosing cervical incompetence, wherein the agent for measuring the gene transcription level is a primer, probe, or antisense nucleotide that specifically binds to the gene.

In addition, the present invention relates to a composition for diagnosing cervical incompetence, in which the agent for measuring the protein expression level is an antibody or antigen-binding fragment thereof that specifically binds to a protein produced from the gene or a fragment thereof.

In addition, the present invention relates to a composition for diagnosing cervical incompetence, wherein the antibody is a polyclonal antibody or a monoclonal antibody.

In addition, the present invention is DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit alpha 1), SLC4A1 (solute carrier family) 4 member 1), ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CRISP3, CEACAM6, PGLYRP1, CHST13, CITED4, CFAP45, OSBPL1A, SIGLEC8, ALOX15, and IDH3A. It relates to a kit for diagnosing cervical incompetence including an agent for measuring gene transcription levels.

In addition, the present invention is DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit alpha 1), SLC4A1 (solute carrier family) 4 member 1), ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CRISP3, CEACAM6, PGLYRP1, CHST13, CITED4, CFAP45, OSBPL1A, SIGLEC8, ALOX15 and IDH3A It relates to a kit for diagnosing cervical incompetence comprising an agent for measuring the expression level of at least one protein.

In addition, the present invention

1) DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit alpha 1), SLC4A1 in biological samples isolated from the subject (solute carrier family 4 member 1), selected from ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CRISP3, CEACAM6, PGLYRP1, CHST13, CITED4, CFAP45, OSBPL1A, SIGLEC8, ALOX15 and IDH3A Measuring the transcription level of one or more genes or the expression level of a protein or fragment thereof produced from the gene; and

2) comparing the measured transcription level or expression level with the transcription level or protein expression level of a normal control;

In addition, in the present invention, step 1) is RT-PCR, competitive RT-PCR (Real-time RT-PCR), RNase protection assay (RPA: RNase protection assay), Northern It relates to a method for providing information related to the diagnosis of cervical incompetence using Northern blotting or a DNA chip.

In addition, the present invention provides a method for providing information related to diagnosis of cervical incompetence, wherein the biological sample is blood, plasma, platelets, serum, ascites fluid, bone marrow fluid, lymph fluid, saliva, tear fluid, mucosal fluid, amniotic fluid, or a combination thereof It is about.

In addition, the present invention measures the transcription level of one or more genes selected from among DEFA3, CXCL10, RNASE3, CRISP3, FOLR3 (folate receptor gamma), MCEMP1 (mast cell-expressed membrane protein 1) and CD177 or the protein level produced from this gene The present invention relates to a composition for diagnosing the prognosis of cervical incompetence, which determines whether a patient with cervical incompetence has a full-term delivery or not, comprising a preparation for cervical incompetence.

In addition, the present invention measures the transcription level of one or more genes selected from DEFA3, CXCL10, RNASE3 and CRISP3 or the protein expression level produced from this gene from a biological sample isolated from a patient with cervical asthenia, and the gene transcription level or protein expression level is The present invention relates to a composition for diagnosing the prognosis of cervical incompetence, which determines that the possibility of full-term delivery after cervical incompetence suture surgery is high when the average value of cervical incompetence patients is higher.

In addition, the present invention is a transcription level of one or more genes selected from FOLR3 (folate receptor gamma), MCEMP1 (mast cell-expressed membrane protein 1) and CD177 from biological samples isolated from cervical asthenia patients, or protein expression produced from these genes The present invention relates to a composition for diagnosing prognosis of cervical incompetence, in which the possibility of full-term delivery after cervical incompetence suture surgery is determined by measuring the gene transcription level or protein expression level is lower than the average value of cervical incompetence patients.

In addition, the present invention relates to a kit for diagnosing the prognosis of cervical incompetence comprising the composition for diagnosing the prognosis of cervical incompetence.

In addition to this, the present invention

1) Transcription level of one or more genes selected from among DEFA3, CXCL10, RNASE3, CRISP3, FOLR3 (folate receptor gamma), MCEMP1 (mast cell-expressed membrane protein 1) and CD177 in biological samples isolated from cervical asthenia patients Measuring the expression level of a protein or fragment thereof produced from the gene; and

2) comparing the measured transcription level or expression level with the average value of the gene transcription level or protein expression level of cervical incompetence patients; to provide information related to prognosis diagnosis of cervical incompetence.

According to the present invention, the level of gene transcription or protein expression, such as DEFA3, can be compared with a normal control group, and if there is a difference, cervical incompetence can be diagnosed.

In addition, according to the present invention, when the level of gene transcription or protein expression, such as CRISP3, is compared with the average value of cervical incompetence patients, full-term delivery or premature birth can be diagnosed after cervical incompetence suture surgery.

Through such a diagnosis, it is possible to predict a safe delivery of a pregnant woman or to treat it early, thereby improving the health of the mother and fetus.

Figure 1. Global gene expression and differential expression analysis of whole blood transcripts. A. Multidimensional scaling (MDS) representing cervical incompetence and normal controls. B. Volcano plot showing global gene-based differential expression in women with cervical incompetence and normal controls. The x-axis corresponds to the logarithm of the fold change difference between groups and the y-axis corresponds to the negative logarithm of the P value. There were 30 differentially expressed genes (red dots) when using an adjusted P value <0.05.
Figure 2. Enriched Gene Ontology (GO) categories (AC) and KEGG (Kyoto Encyclopedia of Genes and Genomes) pathways (D) of cervical asthenia genes. GO comparison for biological processes (A), cells (B) and molecules (C) of genes differentially expressed in cervical asthenia women and controls. Enriched Gene Ontology (GO) categories (DF) and KEGG pathways (G) for genes in CI-preterm versus CI-term women. GO comparison of biological processes (A), cells (B) and molecules (C) of differentially expressed genes between CI-preterm versus CI-term (CI-term) women. All presented GO terms are significantly enriched with adjusted P values <0.01. CI, cervical incompetence.
Figure 3. mRNA expression of selected DEGs in whole blood of CI and control groups (A) and CI-term and CI-preterm groups (B). *Significant difference compared to control group ( P < 0.05). CI, cervical incompetence.
Figure 4. Serum concentrations of alpha-defensin 3 in CI and controls (A). CI, cervical incompetence.

In the following, the configuration of the present invention will be described in more detail with reference to specific embodiments. However, it is apparent to those skilled in the art that the scope of the present invention is not limited only to the description of the examples.

study patient

Patients who exhibited cervical dilatation with visible fetal membranes in the second trimester on microscopy and who had few or no symptoms were considered to have cervical incompetence and were included in the study. Cervical dilatation, loss, and protruding fetal membranes were evaluated by ultrasonography and confirmed by speculum examination. A nitrazine test and/or an Actim Prom™ test (Medix Biochemica, Kauniainen, Finland) was performed to rule out premature rupture of the membrane. Uterine contraction was assessed by patient's perception, electrocardiogram and abdominal palpation. Patients with cervical dilatation were observed for at least 6 hours, and physical examination revealed that cervical ablation was performed except for preterm labor and chorioamnionitis. Diagnostic criteria for clinical chorioamnionitis include one or more of the following: puerperal fever greater than 38°C, maternal or fetal tachycardia (>100 and 160/min, respectively), or uterine tenderness. We excluded women with major fetal malformations, multiple pregnancies, continuous regular uterine contractions, vaginal hemorrhage, membrane rupture, clinical chorioamnionitis, or prophylactic cervical ablation. Additionally, women with systemic symptoms and signs such as cough, fever, vomiting, diarrhea, abnormal skin rash suggestive of viral and bacterial disease that may affect fertility, and women with abnormal liver and kidney function tests on clinical chemistry tests. and women with urinary tract infections in urinalysis were excluded.

Women in the control group (n = 4) were selected from outpatient clinic visits without uterine contractions or fluid leakage, cervical length greater than 3 cm, or cervical dilatation, and confirmed by ultrasonography. To reduce sample heterogeneity, patients with matching maternal and gestational ages were selected. Whole blood samples were obtained from women on the day of CI diagnosis. For the control group, samples were obtained on the day of study enrollment. To validate the RNA sequencing analysis, qRT-PCR and immunoassay experiments were performed using individual sample sets of CI and control. Blood samples for qRT-PCR were collected in PAXgene™ RNA stabilization tubes (QIAGEN, Hilden, Germany), a portion of the blood sample was centrifuged to collect serum, and both blood and serum samples were cryopreserved at -80°C. This study was approved by the Ethics Committee of Gangnam Sacred Heart Hospital, Hallym University (No. 2017-08-014). Written informed consent for study participation was obtained from each individual prior to recruitment.

Library preparation and sequencing

5mL blood was collected in EDTA tubes for RNA sequencing profiling. Total RNA was isolated using TRIzol® RNA Isolation Reagents (Life Technologies, Carlsbad, CA, USA) and stored at -80°C. Concentration and quality of RNA products were determined on an Agilent 2100 bioanalyzer platform (Agilent Technologies, Santa Clara, CA, USA). mRNA sequencing libraries were prepared for total RNA using the Illumina TruSeq Stranded mRNA Sample Preparation Kit (Illumina, San Diego, CA, USA) according to the manufacturer's protocol. The quality and size of libraries were assessed using the Agilent 2100 Bioanalyzer DNA Kit, quantified by qPCR using a CFX96 Real Time System (Bio-Rad, Hercules, CA, USA) and paired-end on a NextSeq500 system (Illumina). 75 base pair and a single 8 base pair index run were sequenced.

Preprocessing and genomic mapping

The sequencing adapters potentially present in the raw data and the raw data quality basis were calibrated by Skewer [13]. The -x AGATCGGAAGAGCACACGTCTGAACTCCAGTCA and -y AGATCGGAAGAGCGTCGTGTAGGGAAAGAGTGT options were used for common adapter sequences in the Illumina TruSeq adapters, and the -q 0 -l 25 -k 3 -r 0.1 -d 0.1 options were used for low-quality 5' and 3' end trimming of the raw data. . After trimming low-quality bases and sequencing adapters, complete high-quality data were mapped to a reference genome using STAR software [14]. The strand-specific library option --library-type = fr-firststrand was applied to the mapping process.

Gene expression quantification and differentially expressed genes ( DEG ) analyze

Data mapped to the reference genome were quantified as gene expression values using Cufflinks with the strand-specific library option, --library-type = fr-firststrand and other default options [15]. Gene annotations from the reference genome hg19 in the UCSC Genome Browser database (https://genome.ucsc.edu) in GTF format were used as a gene model, with expression values expressed as fragments per kilobase of transcript per million fragments of mapped read data. It was calculated. DEGs between CI and control groups, and DEGs between CI-preterm and CI-term delivery groups were analyzed using the Cuffdiff software of the Cufflinks package [16]. Normalized expression values of selected DEGs were clustered with an in-house R script to compare expression profiles between samples. Volcano plots of expression-fold changes and adjusted P-values between the two groups were also plotted using an in-house R script.

Functional enrichment analysis

To examine the biological functional role of differential gene expression between CI and control, we analyzed genes between DEGs and functionally categorized genes, including biological processes in gene ontology, KEGG pathways, and other functional gene sets by g: Profiler version 0.6.7. A set redundancy test was performed [17]. The Benjamini-Hochberg procedure was used to adjust for multiple testing and enrichment was defined if the adjusted P value was less than 0.05. Multi-dimensional scaling (MDS) was used to investigate the efficiency of DEGs related to CI.

DEG's qRT - PCR verification

Total RNA was extracted from frozen blood samples using the PAXgene Blood RNA Isolation Kit (QIAGEN) according to the manufacturer's protocol. RNA quality was verified with an Agilent 2100 Bioanalyzer, and RNA quantification was performed using a NanoDrop® ND-1000 spectrophotometer (Thermo Fisher Scientific, Waltham, MA, USA). Genes were selected based on higher statistical significance, greater absolute fold-change and clinical significance and tested by qRT-PCR to confirm RNA-Seq analysis results. DEFA3 (defensin alpha 3), JUN (jun proto-oncogene), ELANE (neutrophil elastase) and CD177 (CD177 molecule) were selected for validation experiments between CI and control, whereas CEACAM8 (CEA cell adhesion molecule 8), CRISP3 (cysteine-rich secreted protein 3), DEFA3 and RNASE3 (ribonuclease A family member 3) were selected to confirm differential expression between the CI-preterm and CI-term delivery groups. 4 micrograms of RNA were used for cDNA synthesis using the Maxime RT PreMix Kit (iNtRON Biotechnology, Seoul, South Korea). PCR was performed using 2Х Rotor-Gene SYBR Green PCR Master Mix (QIAGEN) in Rotor-Gene Q (QIAGEN). Primer sequences are shown in Table 4. Actin was used as a housekeeping control. Each sample was run three times and all samples had a standard deviation less than 0.5 between the three runs.

serum alpha defensins ELISA for 3

Levels of serum alpha-defensin 3 were determined in duplicate using an ELISA kit (Cusabio, Wuhan, China) according to the manufacturer's instructions. The concentration of alpha-defensin 3 was determined by interpolation from the standard curve. The assay limit of detection was 1.87 ng/mL and the calculated inter- and intra-assay coefficient of variation was <10%.

statistical analysis

Data are presented as mean ± standard deviation or median (interquartile range) for continuous variables and as n (%) for categorical variables. Mann-Whitney U tests were used to make comparisons between CI and control groups, CI - term delivery and CI - preterm groups. Proportions were compared using Fisher's exact test. Statistical analysis was performed using SPSS software (version 23.0, SPSS, Inc., Chicago, IL, USA). P<0.05 was considered statistically significant.

Outcome 1: Study subject

The clinical characteristics of 15 test subjects (CI group, n = 11; control group, n = 4) included in the RNA-Seq analysis are shown in Table 1. Maternal age and gestational age at the time of sampling were not significantly different between the two groups. Four women in the CI group gave birth prematurely [CI-preterm group; gestational age at delivery, 19.8 (17.4-30.9)], the remainder delivered after 37 weeks of gestation [CI-term delivery group; Gestational age at delivery, 38.0 (37.0–39.0)]. The white blood cell (WBC) and neutrophil counts of the CI-preterm delivery group were significantly higher than those of the CI-term delivery group (Table 1).

Result 2: Differentially expressed genes between CI and control

We analyzed genome-wide transcriptomes of blood samples using RNA-Seq for 11 CI and 4 control samples. MDS was performed on the gene expression data to determine similarity patterns between CIs and controls. The MDS plot shows that the control samples are clearly distinct from the CI samples and the CI samples show greater diversity (Fig. 1A). Thirty genes were found to be significantly differentially expressed between CI and control (false discovery rate <0.05, fold change ≥2) (Fig. 1B, Table 2). Of these, 26 genes were significantly up-regulated and 4 were down-regulated in the CI group compared to the control group. Upregulated DEGs include genes related to neutrophil-mediated immunity [DEFA3, CD177, JUN, ELANE, bactericidal permeability increasing protein (BPI), matrix metallopeptidase 8 (MMP8) and CEACAM8)], genes related to bicarbonate transport [(carbonic anhydrase 1 (CA1)) , HBA1 (hemoglobin subunit alpha 1), and SLC4A1 (solute carrier family 4 member 1)]. To understand the underlying biological pathways that were differentially regulated between the two groups, functional enrichment analysis was performed.23 in the category of biological processes. Terms were enriched, and bicarbonate transport, myeloid leukocyte activation, oxygen transport, neutrophil degranulation and neutrophil activation were most significantly enriched for DEGs Similarly, DEGs were enriched with 23 terms in the cellular component category and 5 terms in the molecular function category. KEGG pathway analysis showed that the most enriched pathways were malaria and African trypanosomiasis (FIG. 2D).

Results 3: Between CI-preterm and CI-term delivery groups DEG

Based on the pregnancy results, patients in the CI group were further divided into CI-term delivery (n = 7) and CI-preterm delivery (n = 4) groups, and the DEG between them was investigated. A comparison of clinical characteristics between the two groups is shown in Table 1. A total of 338 genes were differentially expressed (false discovery rate <0.05 and fold-change ≥2) between the CI-term and CI-preterm groups (Tables 5 to 26, Table 5 to Table 26 due to the excessively large table size). Divided into Table 26, Table 5 and Table 6 are tables linked to each other, Tables 7 and 8 are linked tables, and the two tables up to Table 25 and Table 26 are linked tables). Of these, 194 genes were significantly up-regulated and 144 were down-regulated in the CI-term delivery group compared to the CI-preterm group. Immune response and defense response to organism-related genes such as DEFA3, CXCL10 (C-X-C motif chemokine ligand 10), RNASE3 and CRISP3 were up-regulated in the CI-term delivery group, whereas FOLR3 (which is involved in myeloid leukocyte-mediated immunity and neutrophil activation) folate receptor gamma), MCEMP1 (mast cell-expressed membrane protein 1) and CD177 were upregulated in the CI-preterm group. As a result of functional enrichment analysis, DEGs were enriched in 84 terms in the biological process category, with defense response and immune response terms being the most significantly enriched. DEGs were enriched with 32 terms in the cellular component category and 5 terms in the molecular function category (Fig. 2D-F). In addition, the most significantly up-regulated pathways in the KEGG pathway analysis were the influenza A, NOD-like receptor (nucleotide-binding oligomerization domain-like receptor) and RIG-I-like receptor (retinoic acid-inducible gene-I-like receptor) signaling pathways. was (Fig. 2G).

Result 4: DEGs qRT - PCR verification

Four genes (DEFA3, JUN, ELANE and CD177) were selected to validate significant DEGs from the RNA-Seq results and differential expression between individual sample sets of CI (n = 11) and controls (n = 5) was qRT- Evaluated by PCR. Patient demographics and clinical characteristics are presented in Table 27. Four genes showed higher mRNA expression in the CI group than in the control group, consistent with RNA-Seq analysis (Fig. 3A). In addition, the mRNA expression of four genes (DEFA3, RNASE3, CRISP3 and CEACAM8) that differed between the CI-term and CI-preterm groups were evaluated (Fig. 3B). These genes were significantly upregulated in the CI-term delivery group compared to the CI-preterm group, and the results were consistent with those of RNA-Seq analysis.

Outcome 5: Alpha in CI patients defensins 3 expression

RNA-Seq analysis identified DEFA3 as one of the highest upregulated DEGs in the CI group compared to the control group. Also, DEFA3 was significantly upregulated in the CI-term delivery group compared to the CI-preterm delivery group. In addition to this, the DEFA3 mRNA expression pattern was consistent with the results of RNA-Seq analysis. Therefore, an immunoassay was performed to confirm differential expression of serum alpha-defensin 3 in CI patients (n = 25) and normal controls (n = 17). The clinical characteristics of the patients are shown in Table 3. Alpha-defensin 3 was significantly up-regulated in the CI group compared to the control [CI group 14.9 ng/mL (10.5 to 47.2 ng/mL) vs. control 9.9 ng/mL (4.6 to 17.2 ng/mL), p = 0.014; Fig. 4].

Claims (12)

DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit) by polymerase chain reaction from blood samples isolated from test subjects alpha 1), SLC4A1 (solute carrier family 4 member 1), ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CEACAM6, PGLYRP1, CHST13, CITED4, CFAP45, OSBPL1A, SIGLEC8, ALOX15 and A composition for diagnosing cervical incompetence comprising an agent for measuring the transcription level of at least one gene selected from IDH3A.
DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit alpha 1), SLC4A1 from blood samples isolated from the test subject. (solute carrier family 4 member 1), ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CEACAM6, PGLYRP1, CHST13, CITED4, CFAP45, OSBPL1A, SIGLEC8, ALOX15 and IDH3A genes A composition for diagnosing cervical incompetence comprising an agent for measuring the expression level of at least one protein produced from.
According to claim 1 or claim 2,
DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit alpha 1), SLC4A1 (solute carrier family 4 member 1), The transcription level of one or more genes selected from among ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CEACAM6, PGLYRP1, CHST13, CITED4 and CFAP45, or the protein expression level produced from this gene, was higher than that of the normal control group. A composition for diagnosing cervical incompetence, which is judged to be cervical incompetence when increased compared to that of the present invention.
According to claim 1 or claim 2,
When the transcription level of one or more genes selected from OSBPL1A, SIGLEC8, ALOX15 and IDH3A or the protein expression level produced from this gene is reduced compared to the normal control group, cervical incompetence is determined as a composition for diagnosing cervical incompetence.
The method of claim 1,
The agent for measuring the level of gene transcription is a composition for diagnosing cervical asthenia, comprising a primer, probe or antisense nucleotide that specifically binds to the gene.
The method of claim 2,
The agent for measuring the protein expression level is a composition for diagnosing cervical incompetence, comprising an antibody or antigen-binding fragment thereof that specifically binds to a protein produced from the gene or a fragment thereof.
The method of claim 6,
The antibody is a polyclonal antibody or a monoclonal antibody, a composition for diagnosing cervical incompetence.
DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit alpha 1), SLC4A1 from blood samples isolated from the test subject. (solute carrier family 4 member 1), 1 selected from ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CEACAM6, PGLYRP1, CHST13, CITED4, CFAP45, OSBPL1A, SIGLEC8, ALOX15 and IDH3A A kit for diagnosing cervical incompetence comprising an agent for measuring gene transcription levels of at least one species by using a polymerase chain reaction.
DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit alpha 1), SLC4A1 from blood samples isolated from the test subject. (solute carrier family 4 member 1), ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CEACAM6, PGLYRP1, CHST13, CITED4, CFAP45, OSBPL1A, SIGLEC8, ALOX15 and IDH3A genes A kit for diagnosing cervical incompetence comprising an agent for measuring the expression level of at least one protein produced from.
1) DEFA3, CD177, JUN, ELANE, BPI (bactericidal permeability increasing protein), MMP8 (matrix metallopeptidase 8), CEACAM8, CA1 (carbonic anhydrase 1), HBA1 (hemoglobin subunit alpha 1) from blood samples isolated from the test subject , SLC4A1 (solute carrier family 4 member 1), ALAS2, BTNL3, SLC2A14, SELENBP1, HBA2, HBD, MPP6, THNSL2, SERINC2, GADD45G, CEACAM6, PGLYRP1, CHST13, CITED4, CFAP45, OSBPL1A, SIGLEC8, ALOX15 and IDH3A Measuring the transcription level of one or more genes or the expression level of a protein or fragment thereof produced from the gene; and
2) comparing the measured transcription level or expression level with the normal control group's transcription level or protein expression level; a method for providing information related to diagnosis of cervical incompetence.
The method of claim 10,
Step 1) above is RT-PCR, competitive RT-PCR, real-time RT-PCR, RNase protection assay (RPA), Northern blotting ) or a method of providing information related to the diagnosis of cervical incompetence using a DNA chip.
The method of claim 10,
The method of providing information related to the diagnosis of cervical incompetence, wherein the biological sample is one or more of blood, plasma, platelets, and serum.

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