scholarly journals Analysis of XX SRY-Negative Sex Reversal Dogs

Animals ◽  
2020 ◽  
Vol 10 (9) ◽  
pp. 1667 ◽  
Author(s):  
Sara Albarella ◽  
Lisa De Lorenzi ◽  
Elena Rossi ◽  
Francesco Prisco ◽  
Marita Georgia Riccardi ◽  
...  
Keyword(s):  
Copy Number ◽  
Promoter Region ◽  
Molecular Genetic ◽  
Disorders Of Sex Development ◽  
Sex Reversal ◽  
Copy Number Variations ◽  
Genomic Region ◽  
Chromosome 9 ◽  
Economic Losses ◽  
Sex Development

Impaired fertility associated with disorders of sex development (DSDs) due to genetic causes in dogs are more and more frequently reported. Affected dogs are usually of specific breeds thus representing a cause of economic losses for breeders. The aim of this research is to report the clinical, cytogenetic and molecular genetic findings of four XX SRY-negative DSD dog cases. All the subjects showed a female aspect and the presence of an enlarged clitoris with a penis bone. Morphopathological analyses performed in three of the four cases showed the presence of testes in two cases and ovotestis in another. Conventional and R-banded cytogenetic techniques were applied showing that no chromosome abnormalities were involved in these DSDs. CGH arrays show the presence of 11 copy number variations (CNVs), one of which is a duplication of 458 Kb comprising the genomic region between base 17,503,928 and base 17,962,221 of chromosome 9 (CanFam3 genome assembly). This CNV, confirmed also by qPCR, includes the promoter region of SOX9 gene and could explain the observed phenotype.

scholarly journals Integrated small copy number variations and epigenome maps of disorders of sex development

2016 ◽  
Vol 3 (1) ◽  
Author(s):  
Ina E Amarillo ◽  
Isabelle Nievera ◽  
Andrew Hagan ◽  
Vishwa Huchthagowder ◽  
Jennifer Heeley ◽  
...  
Keyword(s):  
Copy Number ◽  
Disorders Of Sex Development ◽  
Copy Number Variations ◽  
Sex Development

DNA Copy Number Variations in Patients with 46,XY Disorders of Sex Development

2014 ◽  
Vol 192 (6) ◽  
pp. 1801-1806 ◽  
Author(s):  
Steven M. Harrison ◽  
Candace F. Granberg ◽  
Melise Keays ◽  
Martinez Hill ◽  
Gwen M. Grimsby ◽  
...  
Keyword(s):  
Copy Number ◽  
Disorders Of Sex Development ◽  
Copy Number Variations ◽  
Dna Copy Number ◽  
Dna Copy Number Variations ◽  
Sex Development

scholarly journals GENETICS IN ENDOCRINOLOGY: Approaches to molecular genetic diagnosis in the management of differences/disorders of sex development (DSD): position paper of EU COST Action BM 1303 ‘DSDnet’

2018 ◽  
Vol 179 (4) ◽  
pp. R197-R206 ◽  
Author(s):  
L Audí ◽  
S F Ahmed ◽  
N Krone ◽  
M Cools ◽  
K McElreavey ◽  
...  
Keyword(s):  
Candidate Genes ◽  
Best Practice ◽  
Molecular Genetic ◽  
Genetic Diagnosis ◽  
Disorders Of Sex Development ◽  
Initial Step ◽  
Copy Number Variations ◽  
Position Paper ◽  
Sex Development ◽  
Complementary Approach

The differential diagnosis of differences or disorders of sex development (DSD) belongs to the most complex fields in medicine. It requires a multidisciplinary team conducting a synoptic and complementary approach consisting of thorough clinical, hormonal and genetic workups. This position paper of EU COST (European Cooperation in Science and Technology) Action BM1303 ‘DSDnet’ was written by leading experts in the field and focuses on current best practice in genetic diagnosis in DSD patients. Ascertainment of the karyotpye defines one of the three major diagnostic DSD subclasses and is therefore the mandatory initial step. Subsequently, further analyses comprise molecular studies of monogenic DSD causes or analysis of copy number variations (CNV) or both. Panels of candidate genes provide rapid and reliable results. Whole exome and genome sequencing (WES and WGS) represent valuable methodological developments that are currently in the transition from basic science to clinical routine service in the field of DSD. However, in addition to covering known DSD candidate genes, WES and WGS help to identify novel genetic causes for DSD. Diagnostic interpretation must be performed with utmost caution and needs careful scientific validation in each DSD case.

scholarly journals Non-Syndromic 46,XY Disorders of Sex Development

2018 ◽  
Vol 18 (1) ◽  
pp. 35-41
Author(s):  
J Gecz ◽  
J Breza ◽  
P Banovcin
Keyword(s):  
Genetic Testing ◽  
Slovak Republic ◽  
Molecular Genetic ◽  
Disorders Of Sex Development ◽  
Gene Variants ◽  
Molecular Genetic Testing ◽  
The Past ◽  
Sex Development

Abstract Non-syndromic 46,XY DSD (disorders of sex development) represent a phenotypically diversiform group of disorders. We focus on the association between gene variants and the most frequent types of non-syndromic 46,XY DSD, options of molecular genetic testing which has surely taken its place in diagnostics of DSD in the past couple of years. We emphasize the need of molecular genetic testing in individuals with non-syndromic 46,XY DSD in Slovak Republic.

Frequency of Common Copy-Number Variations at 15q11.2q13 in Sperm of Healthy Men

2019 ◽  
Vol 159 (2) ◽  
pp. 66-73 ◽  
Author(s):  
Takahiro Kinoshita ◽  
Masashi Mikami ◽  
Tadayuki Ayabe ◽  
Keiko Matsubara ◽  
Hiromi Ono ◽  
...  
Keyword(s):  
Copy Number ◽  
Alcohol Intake ◽  
Negative Binomial ◽  
Smoking Status ◽  
Clinical Information ◽  
Estimating Equation ◽  
Copy Number Variations ◽  
Genomic Region ◽  
Healthy Men ◽  
Significant Difference

The genomic region at 15q11.2q13 represents a hotspot for copy-number variations (CNVs) due to nonallelic homologous recombination. Previous studies have suggested that the development of 15q11.2q13 deletions in sperm may be affected by seasonal factors because patients with Prader-Willi syndrome resulting from 15q11.2q13 deletions on paternally derived chromosomes showed autumn-dominant birth seasonality. The present study aimed to determine the frequency of 15q11.2q13 CNVs in sperm of healthy men and clarify the effects of various environmental factors, i.e., age, smoking status, alcohol intake, and season, on the frequency. Thirty volunteers were asked to provide semen samples and clinical information once in each season of a year. The rates of 15q11.2q13 CNVs were examined using 2-color FISH. The results were statistically analyzed using a generalized estimating equation with negative binomial distribution and a log link function. Consequently, informative data were obtained from 83 samples of 26 individuals. The rates of deletions and duplications ranged from 0.04 to 0.48% and from 0.08 to 0.30%, respectively. The rates were not correlated with the age, smoking status, or alcohol intake. Sperm produced in winter showed 1.2 to 1.4-fold high rates for both deletions and duplications as compared with sperm produced in the other seasons; however, there was no significant difference. These results demonstrate high and variable CNV rates at 15q11.2q13 in sperm of healthy men. These CNVs appear to occur independent of the age, smoking status, or alcohol intake, while the effect of season remains inconclusive. Our results merit further validation.

scholarly journals Etiology and Clinical Presentation of Disorders of Sex Development in Kenyan Children and Adolescents

2019 ◽  
Vol 2019 ◽  
pp. 1-9
Author(s):  
Prisca Amolo ◽  
Paul Laigong ◽  
Anjumanara Omar ◽  
Stenvert Drop
Keyword(s):  
Children And Adolescents ◽  
Sex Chromosome ◽  
Clinical Laboratory ◽  
Molecular Genetic ◽  
Management Strategies ◽  
Disorders Of Sex Development ◽  
Ambiguous Genitalia ◽  
Molecular Genetic Analysis ◽  
High Rate ◽  
Sex Development

Objective. The purpose of this study was to describe baseline data on etiological, clinical, laboratory, and management strategies in Kenyan children and adolescents with Disorders of Sex Development (DSD). Methods. This retrospective study included patients diagnosed with DSD who presented at ages 0–19 years from January 2008 to December 2015 at the Kenyatta National (KNH) and Gertrude’s Children’s (GCH) Hospitals. After conducting a search in the data registry, a structured data collection sheet was used for collection of demographic and clinical data. Data analysis involved description of the frequency of occurrence of various variables, such as etiologic diagnoses and patient characteristics. Results. Data from the records of 71 children and adolescents were reviewed at KNH (n = 57, 80.3%) and GCH (n = 14, 19.7%). The mean age at the time of diagnosis was 2.7 years with a median of 3 months. Thirty-nine (54.9%) children had karyotype testing done. The median age (IQR) of children with reported karyotypes and those without was 3.3 years (1.3–8.9) and 8.3 years (3.6–12.1), respectively (p=0.021). Based on karyotype analysis, 19 (48.7%) of karyotyped children had 46,XY DSD and 18 (46.2%) had 46,XX DSD. There were two (5.1%) children with sex chromosome DSD. Among the 71 patients, the most common presumed causes of DSD were ovotesticular DSD (14.1%) and CAH (11.3%). Majority (95.7%) of the patients presented with symptoms of DSD at birth. The most common presenting symptom was ambiguous genitalia, which was present in 66 (93.0%) patients either in isolation or in association with other symptoms. An ambiguous genitalia was initially observed by the patient’s mother in 51.6% of 62 cases despite the high rate (84.7%) of delivery in hospital. Seventeen (23.9%) of the cases had a gender reassignment at final diagnosis. A psychologist/psychiatrist or counselor was involved in the management of 23.9% of the patients. Conclusion. The commonest presumed cause of DSD was ovotesticular DSD in contrast to western studies, which found CAH to be more common. Investigation of DSD cases is expensive and needs to be supported. We would have liked to do molecular genetic analysis outside the country but financial challenges made it impossible. A network for detailed diagnostics in resource-limited countries would be highly desirable. There is a need to train health care workers and medical students for early diagnosis. Psychological evaluation should be carried out for all patients at diagnosis and support given for families.

scholarly journals Biosimulation Using the Cellworks Computational Omics Biology Model (CBM) Identifies Immune Modulation As a Key Pathway for Predicting Azacitidine (AZA) Response in Myelodysplastic Syndromes (MDS)

Blood ◽  
2021 ◽  
Vol 138 (Supplement 1) ◽  
pp. 3690-3690
Author(s):  
Scott C Howard ◽  
Ansu Kumar ◽  
Michael Castro ◽  
Himanshu Grover ◽  
Subrat Mohapatra ◽  
...  
Keyword(s):  
Myelodysplastic Syndromes ◽  
Copy Number ◽  
Antigen Processing ◽  
Immune Modulation ◽  
Copy Number Variations ◽  
Chromosome 9 ◽  
Protein Network ◽  
Patient Specific ◽  
Clinical Approach ◽  
Chromosome 9P

Abstract Background: DNA methyltransferase inhibition (DNMTi) with the hypomethylating agents (HMA) azacitidine (AZA) or decitabine, remains the mainstay of therapy for the majority of high-risk Myelodysplastic Syndromes (MDS) patients. Nevertheless, only 40-50% of MDS patients achieve clinical improvement with DNMTi. There is a need for a predictive clinical approach that can stratify MDS patients according to their chance of benefit from current therapies and that can identify and predict responses to new treatment options. Ideally, patients predicted to be non-responders (NR) could be offered alternative strategies while being spared protracted treatment with HMA alone that has a low likelihood of efficacy. Recently, an intriguing discovery of immune modulation by HMA has emerged. In addition to the benefits of unsilencing differentiation genes and tumor suppressor genes, HMA's reactivate human endogenous retroviral (HERV) genes leading to viral mimicry and upregulation of the immune response as a major mechanism of HMA efficacy. Although the PD-L1/PD1 blockade plus HMA has been recognized as a beneficial combination, there are no established markers to guide decision-making. We report here the utility of immunomic profiling of chromosome 9 copy number status as a significant mechanism of immune evasion and HMA resistance. Methods: 119 patients with known clinical responses to AZA were selected for this study. Publicly available data largely from TCGA and PubMed was utilized for this study. The aberration and copy number variations from individual cases served as input into the Cellworks Computation Omics Biology Model (CBM), a computational biology multi-omic software model, created using artificial intelligence heuristics and literature sourced from PubMed, to generate a patient-specific protein network map. Disease-biomarkers unique to each patient were identified within protein network maps. The Cellworks Biosimulation Platform has the capacity to biosimulate disease phenotypic behavior and was used to create a disease model and then conduct biosimulations to measure the effect of AZA on a cell growth score comprised of a composite of cell proliferation, viability, apoptosis, metastasis, and other cancer hallmarks. Biosimulation of drug response was conducted to identify and predict therapeutic efficacy. Results: Although AZA treatment increased tumor associated antigens and interferon signaling, it also increased PD-L1 expression to inactivate cytotoxic CD8(+) T cells. Copy number alterations of the chromosome 9p region were found to significantly drive PD-L1 expression with multiple genes such as CD274, IFNA1, IFNA2, JAK2, PDCD1LG and KDM4C playing a role in PD-L1 regulation further increasing immune suppression (Figure 1). Among 6 cases of chromosome 9p aberration in this dataset, 9p amp (n=2) were clinical non-responders (NR) while 9p del (n=4) were responders (R) to AZA. In principle, checkpoint immunotherapy could improve outcomes for patients with 9p abnormalities. Additionally, copy number variation loss of key genes located on chromosome 16 involved in antigen processing and presentation such as CIITA, CTCF, IRF8, PSMB10, NLRC5, and SOCS1 were found to negatively impact AZA sensitivity (NR=4; R=0); these patients would also be unlikely to respond to checkpoint immunotherapy. Also, aberrations in melanoma antigen gene (MAGE) family proteins (NR=2; R=O), and STT3A (NR=1; R=5) were found to impact AZA efficacy by decreasing antigen processing on tumor cells. Conclusion: Based on the results from the Cellworks Biosimulation Platform applied to the CBM, copy number variants of chromosome 9p and 16 can be converted into CBM-derived biomarkers for response to checkpoint immunotherapy in combination with HMA. Our results support a future prospective evaluation in larger cohorts of MDS patients. Figure 1 Figure 1. Disclosures Howard: Servier: Consultancy; Cellworks Group Inc.: Consultancy; Sanofi: Consultancy, Other: Speaker fees. Kumar: Cellworks Group Inc.: Current Employment. Castro: Bugworks: Consultancy; Exact sciences Inc.: Consultancy; Guardant Health Inc.: Speakers Bureau; Cellworks Group Inc.: Current Employment; Caris Life Sciences Inc.: Consultancy; Omicure Inc: Consultancy. Grover: Cellworks Group Inc.: Current Employment. Mohapatra: Cellworks Group Inc.: Current Employment. Kapoor: Cellworks Group Inc.: Current Employment. Tyagi: Cellworks Group Inc.: Current Employment. Nair: Cellworks Group Inc.: Current Employment. Suseela: Cellworks Group Inc.: Current Employment. Pampana: Cellworks Group Inc.: Current Employment. Lala: Cellworks Group Inc.: Current Employment. Singh: Cellworks Group Inc.: Current Employment. Shyamasundar: Cellworks Group Inc.: Current Employment. Kulkarni: Cellworks Group Inc.: Current Employment. Narvekar: Cellworks Group Inc.: Current Employment. Sahni: Cellworks Group Inc.: Current Employment. Raman: Cellworks Group Inc.: Current Employment. Balakrishnan: Cellworks Group Inc.: Current Employment. Patil: Cellworks Group Inc.: Current Employment. Palaniyeppa: Cellworks Group Inc.: Current Employment. Balla: Cellworks Group Inc.: Current Employment. Patel: Cellworks Group Inc.: Current Employment. Mundkur: Cellworks Group Inc: Current Employment. Christie: Cellworks Group Inc.: Current Employment. Macpherson: Cellworks Group Inc.: Current Employment. Marcucci: Abbvie: Other: Speaker and advisory scientific board meetings; Novartis: Other: Speaker and advisory scientific board meetings; Agios: Other: Speaker and advisory scientific board meetings.

scholarly journals 22q13 Duplication in Newborn With Dysmorphic Features: The Role of SOX10 in Disorders of Sex Development

2021 ◽  
Vol 5 (Supplement_1) ◽  
pp. A689-A690
Author(s):  
Batoul Hammoud ◽  
Natalie Marie Hecht Baldauff ◽  
Svetlana Yatsenko ◽  
Selma Feldman Witchel
Keyword(s):  
Cleft Lip ◽  
Cleft Lip And Palate ◽  
Chromosome Complement ◽  
Disorders Of Sex Development ◽  
Sex Reversal ◽  
Total Testosterone ◽  
Sry Gene ◽  
Nasal Bridge ◽  
Dysmorphic Features ◽  
Sex Development

Abstract Background: The 46,XX testicular disorder of sex development (DSD), also known as 46,XX male reversal, is a rare form of DSD and clinical phenotype shows complete sex reversal from female to male. The sex-determining region Y (SRY) gene can be identified in most 46,XX testicular DSD patients; however, approximately 20% are SRY-negative. Here we present a 2 week old with discrepant prenatal karyotype and infant phenotype. Case: This 2-week-old had dysmorphic features (bitemporal narrowing, broad and flat nasal bridge, bilateral epicanthal folds) and multiple congenital anomalies; IUGR, hypertelorism, cleft lip and palate, ASD, small kidneys, sacral dimple. Physical exam revealed palpable inguinal masses and microphallus without hypospadias. Postnatal karyotype showed a 46,XX chromosome complement with duplication of 22q13-qter. He was negative for SRY gene by FISH. Microarray analysis confirmed the duplication encompassing the SOX10 gene. Lab evaluation showed LH 10.81 mIU/ml, FSH 3.21 mIU/ml and total testosterone 241 ng/dl. These values are consistent with activation of the hypothalamic–pituitary–gonadal axis during the neonatal period in males. Conclusion: Our case along with previous cases supports the existence of a gene on chromosome 22q that can trigger testis determination in the absence of SRY. Potential mechanisms responsible for ovotesticular disorder in the XX (SRY−) individual could involve activation of testis specifying genes in the absence of SRY and/or inadequate expression of pro-ovary/anti-testis genes such as SOX 8 and SOX9. SOX10, a gene closely related to SOX9 and SOX8, and its overexpression has been suggested as a candidate for 46,XX DSD. Over-expression of SOX10 in mice resulted in the XX DSD. The spectrum of sex reversal phenotypes and gonadal asymmetry seen in the Sox10 transgenic mice closely mirrors the range of gonadal and reproductive tract anomalies seen in cases of partial duplication of human chromosome 22q13. Although SRY-negative 46,XX testicular DSD is a rare condition, an effort to make an accurate diagnosis is important for the provision of proper genetic counseling and for guiding patients in their long-term management.

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