Determination of bovine fetal sex by PCR using fetal fluid aspirated by transvaginal ultrasound-guided amniocentesis

Fetal sex can be determined by the polymerase chain reaction (PCR) using cells from fetal fluid collected by transvaginal ultrasound-guided amniocentesis. A total of 35 aspirates from 30 cows, 15 Holsteins and 15 Japanese Blacks at 59 to 250 d of pregnancy were used. Five cows were aspirated twice at a 10-d interval. A 5.0 MHz convex array transducer connected to a scanner was inserted into the vagina under caudal epidural anesthesia. The transducer was equipped with a 65-cm long, 21-g needle within the probe carrier. A bovine male-specific primer and a bovine gender-neutral primer were used. Fetal fluid was obtained from all except 2 cows in early pregnancy. Five animals aborted within 1 wk following aspiration. A total of 33 samples, 29 of amniotic fluid and 4 of allantoic fluid, was subjected to PCR analysis. Fetal gender was verified in 31 33 samples (18 females and 13 males). Gender was also determined by gross examination of external genitalia of offspring after calving or abortion. Fetal gender was correctly identified by PCR analysis of aspirated fetal fluid in 16 16 females and in 13 15 males. Transvaginal ultrasound-guided amniocentesis followed by PCR analysis of aspirated cell DNA can be used accurately to determine fetal sex in cows at 70 to 100 d of gestation. The procedure requires considerable skill and is not without some risk to fetal viability.     

Bovine fetal fluid cells in vitro: Fate and fetal sex prediction accuracy

Summary The in vitro fate of bovine fetal fluid cells and the efficiency of fetal sex prediction from cultures of these cells are studied using aspirates from live animals and pregnant uteri collected from the slaughterhouse. Over 70% of bovine amniotic fluid samples aspirated from pregnant uteri at the time of slaughter yielded cultures adequate for chromosome analysis, whereas only 10% of allantoic fluid samples produced growth of cells satisfactory for chromosome analysis. Fetal sexing accuracy was 100% in all samples studied. Seven readily recognizable cell types were noted in cultures of fetal fluid cells obtained at various stages of gestation. In a majority of cases, the in vitro morphology of cells from both fetal cavities was similar to that observed in primary human amniotic fluid cell cultures.     

Bovine fetal fluid cells in vitro: fate and fetal sex prediction accuracy

The in vitro fate of bovine fetal fluid cells and the efficiency of fetal sex predication from cultures of these cells are studied using aspirates from live animals and pregnant uteri collected from the slaughterhouse. Over 70 percent of bovine amniotic fluid samples aspirated from pregnant uteri at the time of slaughter yielded cultures adequate for chromosome analysis whereas only 10 percent of allantoic fluid samples produced growth of cells satisfactory for chromosome analysis. Fetal sexing accuracy was 100 percent in all samples studied. Seven readily recognizable cell types were noted in cultures of fetal fluid cells obtained at various stages of gestation. In a majority of cases, the in vitro morphology of cells from both fetal cavities was similar to that observed in primary human amniotic fluid cell cultures.     

Fetal fluid steroids and their relationship to gonadal steroid secretion in single and twin bovine fetuses

Steroid concentrations in the fetal fluids of 153 single and 69 twin bovine pregnancies, ranging in age from 35 to 125 d of gestation, were studied to compare gonadal steroid secretions in vitro with the concentrations found in amniotic and allantoic fluids during the early stages of sex differentiation. Among the steroids measured in fetal fluids, only the testosterone level showed a correlation with the amount secreted by the gonads. Significantly higher concentrations of testosterone were associated with male fetuses than with female fetuses. The concentrations of androstenedione, estradiol and estrone in both fetal fluid compartments were generally correlated with age, reflecting the extra-gonadal source of steroids in these fluids. Androstenedione levels in fetal fluids were significantly higher in twins than in singletons, suggesting that this parameter may be useful for the diagnosis of fetal sex and/or type of pregnancy.     

Androgen level in the sheep fetus during gestation.

The androgen content of amniotic fluid, plasma, and gonads from 107 fetal lambs was determined by radioimmunoassay in an attempt to understand the ontogeny of gonadal function. Testosterone (T) was too low to be reliably measured in the amniotic fluid from fetuses of either sex. Ovaries were without T activity at any of the stages of gestation studied. Testicular T-5alpha-dihydrotestosterone (T-DHT) concentration steadily decreased from 1.4/ml near term. It is suggested that nongonadal testosterone production increases during fetal life and that T secretion by the fetal testis may contribute steadily less to the plasma pool of T as gestation proceeds.     

Relationships between sex hormones assessed in amniotic fluid, and maternal and umbilical cord serum: what is the best source of information to investigate the effects of fetal hormonal exposure?

Levels of testosterone (T) (total and free), androstenedione (A4), dehydroepiandrosterone sulphate (DHEAS), sex hormone-binding globulin (SHBG), and estradiol (E2) were measured by radioimmunoassay (RIA) in 156 normal pregnancies (77 male and 79 female fetuses). Samples were obtained from amniotic fluid, 2nd and 3rd trimester maternal serum, and umbilical cord serum at birth. During the critical period of brain differentiation, at the beginning of the second trimester of pregnancy, sex differences in T and A4 were found in amniotic fluid and not in maternal serum. This finding adds to the fact that mostly low and nonsignificant correlations were found for the different androgenic hormones between levels assessed in amniotic fluid and maternal plasma at this particular and very sensitive period of fetal brain development. On the other hand, high correlations were found for the same hormones between the samples of maternal serum in the 2nd and the 3rd trimester. Our data show that, of all available sources, amniotic fluid seems to be the best candidate to investigate the effects of early fetal androgen exposure.     

Chromosome Analysis before Birth and its Value in Genetic Counselling

Chromosome analysis of amniotic cell cultures was achieved in 29 out of 30 consecutive patients who were referred for genetic counselling during pregnancy. Amniocentesis was performed without any apparent untoward maternal or fetal complication. The only pregnancy terminated was that of a carrier of X-linked granulomatous disease, in whom the amniotic cells showed that the fetus was male and also had Down''s syndrome (trisomy G). Chromosome analysis in the remaining 28 patients showed normal karyotypes. The interval between amniocentesis and a definitive karyotype varied from 7 to 31 (average 18·4) days.The reliability of chromosome analysis from amniotic cell culture and of fetal sex determination by means of the sex chromatin and Y-fluorescence techniques was studied further in amniotic fluid from cases of therapeutic abortion and of rhesus incompatibility. The fetal sex was correctly determined in all cases. It is concluded that antenatal diagnosis of genetic disease by amniocentesis now permits a more practical approach to genetic counselling.     

Alternative strategies of fetal sex diagnoses and sex preselection

Abstract

Motives for sex control include avoidance of sex‐linked disease and realization of preferred sex compositions of children. Currently, the only wholly effective means of sex control is diagnosis of fetal sex by mid‐trimester karyotyping of amniotic fluid cells followed by corrective abortion when diagnosis is adverse. Unfortunately the delays involved in karyotyping mean that abortion cannot be minimum‐risk suction curretage. Radioimmunoassay procedures allow somewhat earlier diagnosis and therefore less risky abortion, but entail more diagnostic error. In the first part of the paper, several assay procedures are evaluated in terms of relative expense as compared to karyotyping, gestational age when reliability is highest, and level of that reliability. Later portions of the paper focus on use of radioimmunoassay to diagnose fetal sex for purposes of regulating the sex composition of offspring. Three strategies are compared with respect to their efficiency and expected levels of diagnosis and abortion.     

Composition of the fetal fluids in African antelopes

Twenty-four samples of amniotic and allantoic fetal fluids were collected from 15 African antelopes of 11 species and subspecies. Two samples were taken from delivered placentas and the rest were from animals that died during pregnancy or parturition. Data on the sex, development (crown-rump length) and age (trimester of pregnancy) of fetuses, fluid volumes, pH, and 18 biochemical parameters were obtained wherever conditions permitted. Collecting data on fetal fluids in zoo and wild animals may help evaluate both normal and pathological pregnancies.     

The influence of androgen status on metabolic activity in the rat epididymis

Forty-two bovine fetal fluid samples (29 by transsacrosciatic amniocentesis, 2 by transischiorectal amniocentesis, 11 from slaughter-house material) were set up in tissue culture. Thirteen cultures failed due to either incubator failure, bacterial or fungal contamination, or the paucity of culturable cells. Sufficient growth for sex chromosome analysis was obtained in 29 smaples. Twenty-four of these were correctly sexed, three could not be verified and two were incorrectly sexed.Contamination of fetal fluid samples with maternal cells was found to be a major problem which could lead to the misinterpretation of results. To minimize this possibility: the first 1–2 ml of aspirated fetal fluids must be discarded; multiple cultures should be initiated from each sample; and when male cells are not observed, numerous metaphase spreads from each culture and from several passages must be analyzed.     

Tracking fetal development through molecular analysis of maternal biofluids

Current monitoring of fetal development includes fetal ultrasonography, chorionic villus sampling or amniocentesis for chromosome analysis, and maternal serum biochemical screening for analytes associated with aneuploidy and open neural tube defects. Over the last 15 years, significant advances in noninvasive prenatal diagnosis (NIPD) via cell-free fetal (cff) nucleic acids in maternal plasma have resulted in the ability to determine fetal sex, RhD genotype, and aneuploidy. Cff nucleic acids in the maternal circulation originate primarily from the placenta. This contrasts with cff nucleic acids in amniotic fluid, which derive from the fetus, and are present in significantly higher concentrations than in maternal blood. The fetal origin of cff nucleic acids in the amniotic fluid permits the acquisition of real-time information about fetal development and gene expression. This review seeks to provide a comprehensive summary of the molecular analysis of cff nucleic acids in maternal biofluids to elucidate mechanisms of fetal development, physiology, and pathology. This article is part of a Special Issue entitled: Molecular Genetics of Human Reproductive Failure.     

Ultrasonographic fetometry and prenatal fetal sex assessment in camels (Camelus dromedarius)

The aims of this study were to determine the developmental patterns of some fetal parts to achieve a high accuracy level in the assessment of gestational age and to assess the feasibility and accuracy of ultrasonic prenatal fetal sex assessment in camels. Serial ultrasonographic examinations were carried out on seven pregnant dromedary camels. A total of 329 ultrasonographic examinations were conducted between the second and the 54th weeks of pregnancy. Intrauterine fluid accumulation was detected between the second and third weeks of pregnancy. The embryo proper was noticed between the third and fourth weeks. Organization of the embryo was first observed between the sixth and seventh weeks. Ossification was first detected between the seventh and ninth weeks. The accessibility during the total gestational period was 35/329 (10.6%) for crown-rump length, 35/329 (10.6%) for biparietal diameter, 42/329 (12.8%) for abdominal diameter, 42/329 (12.8%) for ruminal length, and 126/329 (38.3%) for eyeball diameter. A high correlation was found between gestational age and each of the studied parameters (P < 0.0001). The highest correlation was found with the crown-rump length and the biparietal diameter during the first trimester and with the eyeball diameter during the third trimester of pregnancy. The overall accuracy of the ultrasonic prenatal fetal sex assessment was 91.7%. The best window was found during the 11th week of pregnancy. It was concluded that sonographic fetometry can be useful for the evaluation of fetal development, the estimation of gestational age, and the prediction of prenatal fetal sex in camels.     

Maternal or fetal origin of rhesus monkey (Macaca mulatta) amniotic fluid leukocytes can be identified by polymerase chain reaction using the zinc finger Y gene.

Leukocytes can be found in substantial numbers within the intrauterine tissues and amniotic fluid of women, and play a central role in the pathophysiology of infection-related preterm labor by their production of proinflammatory mediators. It remains unclear whether these leukocytes represent a fetal immune response, a maternal response, or a combination of the two. The objective of this study was to develop a test in the rhesus monkey (Macaca mulatta) suitable for determining the percentage of male fetal cells present in a population of leukocytes recovered from blood or amniotic fluid. We found inadequate specificity for rhesus monkey cells using commercial human Y-chromosome paint kits (fluorescence in situ hybridization (FISH)). Human-specific primers for the repetitive Y chromosome DYZ-1 locus employed in the polymerase chain reaction (PCR) produced an unacceptable percentage of false positives. However, we successfully developed a PCR-based test using rhesus-specific primers for the zinc finger Y (ZFY) locus. Densitometry of PCR products from known ratios of male and female adult peripheral leukocytes generated a linear standard curve which provided quantitative results and required only 400 cells per sample. The rhesus beta globin (RBG) gene served as an internal control. The PCR test correctly discriminated the sex of peripheral leukocytes in 20 adult males, 20 adult females, two male fetuses, and one female fetus. Serial samples of amniotic fluid from four chronically catheterized rhesus monkeys bearing male fetuses were used to confirm the utility of this assay for quantifying fetal cells in amniotic fluid. In conclusion, we have developed a PCR test which is suitable for distinguishing male from female cells in adult and fetal blood and in amniotic fluid, which lends itself to a variety of diagnostic and biologic applications in the rhesus monkey and potentially in other nonhuman primates.     

Prenatal exposure to dexamethasone in the mouse induces sex‐specific differences in placental gene expression

Prenatal stress during pregnancy leads to sex‐specific effects on fetal development and disease susceptibility over the life span; however, the origin of sex differences has not been identified. The placenta not only plays a key role in fetal growth and development throughout pregnancy, but also affects the fetal programming underlying subsequent adult health and accounts. Therefore, sex‐specific adaptation of the placenta may be central to the sex differences in fetal growth and survival. Here, we analyzed the effects of prenatal dexamethasone (Dex) on sex‐specific changes in placental gene expression using RNA‐Seq. Placental tissues from males and females were separated into two developmentally distinct fetal and maternal parts at E11.5 stage. The majority of genes in female placentas were downregulated by prenatal Dex, whereas those were mostly maintained or rather upregulated in male placentas. RNA‐Seq results were validated using independent biological replicates from the same stage and placental tissue samples from E18.5 by realtime PCR assays. Activation of various inflammatory response‐related genes, chemokines and their receptors, particularly in male placentas, strongly implies that prenatal Dex exposure causes sex‐specific physiological responses that can lead to inflammatory diseases involving vascular pathology.     

Noninvasive Fetal Sex Determination by Real-Time PCR and TaqMan Probes

Background:Noninvasive fetal sex determination by analyzing Y chromosome-specific sequences is very useful in the management of cases related to sex-linked genetic diseases. The aim of this study was to establish a non-invasive fetal sex determination test using Real-Time PCR and specific probes.Methods:The study was a prospective observational cohort study conducted from August 2018 to September 2019. Venous blood samples were collected from 25 Iranian pregnant women at weeks 7 to 25 of gestation. Cell-free DNA (cfDNA) was isolated from the plasma of samples and fetal sex was determined by SRY gene analysis using the Real-Time PCR technique. In the absence of SRY detection, the presence of fetal DNA was investigated using cfDNA treated with BstUI enzyme and PCR for the epigenetic marker RASSF1A.Results:Of the total samples analyzed, 48% were male and 52% female. The RASSF1A assay performed on SRY negative cases also confirmed the presence of cell-free fetal DNA. Genotype results were in full agreement with neonate gender, and the accuracy of noninvasive fetal sex determination was 100%.Conclusion:Fetal sex determination using the strategy applied in this study is noninvasive and highly accurate and can be exploited in the management of sex-linked genetic diseases.Key Words: Cell-free fetal DNA, Fetal sex determination, Noninvasive prenatal diagnosis, Sex-linked genetic diseases, SRY     

利用孕妇血浆DNA检测胎儿性别的研究

本文探讨应用孕妇血浆中游离DNA进行无创性产前性别诊断的可行性。用柱分离法提取73例孕妇血浆中DNA,用巢式PCR技术检测其胎儿SRY基因。 结果73位孕妇血浆DNA含量为0.0062~0.3399μg/μL。巢式PCR检测胎儿SRY基因的灵敏度为97.37%（37/38）,假阴性率2.86%(1/35),特异度85.71%（30/35）,假阳性率13.16%(5/38),总符合率91.78%（67/73）。采用孕妇血浆胎儿DNA和巢式PCR技术可以快速简便的进行无创性产前性别诊断,诊断结果的准确率为91.8%,对性连锁遗传病的预防具有重要意义。 Abstract:To investigate the feasibility and possibility of application of fetal DNA from maternal plasma for noninvasive prenatal diagnosis of fetal sex,plasma DNAs in blood samples of 73 pregnant women at the gestational period of 26 to 41 weeks were extracted by column separation and nested polymerase chain reaction were employed to amplify the SRY gene.A comparison was made between the amplification results and the real sex of the fetus after their delivery.The concordance rate of SRY gene amplification results of plasma free DNA with real fetal sex was 91.78% (67/73),the sensitivity rate was 97.37% (37/38),and the specific rate was 85.71% (30/35).The cell-free fetal DNA in maternal blood can be one of the valuable material sources for noninvasive prenatal diagnosis and the method of nested PCR could be useful for fetal sex determination.The specific rate of the test was 91.78%.It is of significance to prevent sex-linked inheritant diseases.     

Effect of the in vitro culture system on the kinetics of blastocyst development and sex ratio of bovine embryos

Bovine blastocysts were produced using 6 different systems: 5 commonly used in vitro culture systems (synthetic oviduct fluid medium - SOF- without fetal calf serum, SOF supplemented with 10% serum for the entire culture period, SOF supplemented with 10% serum from Day 4 of culture, M199 coculture with bovine oviduct epithelial cells, M199 coculture with granulosa cell monolayer) and 1 in vivo culture system involving collection of blastocysts from superovulated bovine donors at Day 7. Zygotes obtained from IVM/IVF were assigned randomly to 1 of the 5 systems tested and were cultured for 9 d (Day 0= day of insemination). Cleavage, development to the blastocyst stage and blastocyst sex ratio were assessed in all treatments. In addition, the effect of the IVC system on the kinetics of blastocyst development and sex ratio was assessed on Days 6, 7, 8, and 9. The presence of fetal calf serum in SOF not only resulted in faster development (19.1% of blastocysts in SOF supplemented with serum vs 7.1% in absence of serum at Day 6; P < 0.05) and increased blastocyst production (47.5% of blastocysts in SOF supplemented with serum vs 34.4% in absence of serum; P < 0.05) but it also enhanced overall male survival. The coculture systems produced fewer blastocysts than culture in SOF (27.6 to 28.3% in coculture vs 47.5% in SOF supplemented with serum; P < 0.05), but similar to SOF without fetal calf serum, they had no effect on blastocyst sex ratio.     

Lack of correlation of severity of lung disease with the phosphatidylcholine concentration in fetal lung fluid from premature lambs at 133-136 days gestational age

Fetal lung fluid was collected following tracheotomy at the time of delivery of 40 premature lambs at 133-136 days gestational age. The concentration of phosphatidylcholine and saturated photophatidylcholine in fetal lung fluid was compared with the severity of lung disease of the lambs as assessed after 3 to 10 h of controlled mechanical ventilation with only peak inspiratory pressures varied to control the PCO2 values. Phosphatidylcholine concentration in fetal lung fluid did not correlate with the peak inspiratory pressures needed to ventilate the lambs, total lung compliance values, or the surfactant phosphatidylcholine pool sizes measured by alveolar wash after sacrifice. The ratio of saturated to total phosphatidylcholine was constant (0.55 +/- 0.02) and independent of concentration of phosphatidylcholine in the fetal lung fluid. The fetal lung fluid contained only about 0.7% of the final surfactant phosphatidylcholine pool released by the lambs to the alveoli after birth. Within a narrow gestational age range characterized by lung disease of widely varying severity, the phosphatidylcholine concentrations in fetal lung fluid were not predictive of the severity of lung disease.     

Fetal gender determination by first-trimester ultrasound in dairy cows under routine herd management in Northwest Spain

Ultrasonography (US) provides detailed visualization of the fetus in early pregnancy in cows, thus allowing for fetal sex determination. The objective of this prospective observational study was to determine the feasibility and accuracy of a single US examination to diagnose fetal sex in dairy cattle under routine reproductive management conditions. For this purpose, 953 Holstein cows at 7-16 weeks of gestation were examined. Gender assignment was performed in 822 cows, while the genitalia could not be clearly visualized in 131 (13.7%) of the fetuses. After calving, it was verified that 99.3% of the diagnoses were accurate. Fetal sex was correctly determined by US in 99.5% of male fetuses and 98.8% of female fetuses. Fetal sex determination was less accurate when conducted before d 55 of gestation. Likewise, it was verified that fetal sex, cow age and ultrasonographic diagnosis section did not have a significant influence (P>0.05) on diagnostic accuracy. With respect to the plane used for diagnosis, the sagittal view was poorly used for early pregnancy diagnosis, whereas the longitudinal and cross-sectional planes were used most frequently. These results demonstrate that US can be routinely applied under farm conditions to accurately determine the fetal sex in cattle between days 51 and 111 of gestation without apparent influence of cow age, US scanning plane or fetal sex. Conversely, days of gestation affected the accuracy and feasibility of US gender determination, showing poorer results when the diagnosis was made before day 55 of gestation.