Clinical Overview > Gland/Organ > Testes

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Jasmeet Kaur Laboratory of Biochemistry, Biomedical Sciences, Mercer University School of Medicine, Savannah, Georgia, USA
Anderson Cancer Institute, Memorial University Medical Center, Savannah, Georgia, USA

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Alan M Rice Division of Pediatric Endocrinology, Memorial University Medical Center, Savannah, Georgia, USA
Augusta University School of Medicine, Augusta, Georgia, USA
Neonatology Intensive Care Unit, Memorial University Medical Center, Georgia, USA

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Elizabeth O’Connor Laboratory of Biochemistry, Biomedical Sciences, Mercer University School of Medicine, Savannah, Georgia, USA

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Anil Piya Division of Pediatric Endocrinology, Memorial University Medical Center, Savannah, Georgia, USA
Neonatology Intensive Care Unit, Memorial University Medical Center, Georgia, USA

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Bradley Buckler Neonatology Intensive Care Unit, Memorial University Medical Center, Georgia, USA

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Himangshu S Bose Laboratory of Biochemistry, Biomedical Sciences, Mercer University School of Medicine, Savannah, Georgia, USA
Anderson Cancer Institute, Memorial University Medical Center, Savannah, Georgia, USA

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Congenital adrenal hyperplasia (CAH) is caused by mutations in cytochrome P450 side chain cleavage enzyme (CYP11A1 and old name, SCC). Errors in cholesterol side chain cleavage by the mitochondrial resident CYP11A1 results in an inadequate amount of pregnenolone production. This study was performed to evaluate the cause of salt-losing crisis and possible adrenal failure in a pediatric patient whose mother had a history of two previous stillbirths and loss of another baby within a week of birth. CAH can appear in any population in any region of the world. The study was conducted at Memorial University Medical Center and Mercer University School of Medicine. The patient was admitted to Pediatric Endocrinology Clinic due to salt-losing crisis and possible adrenal failure. The patient had CAH, an autosomal recessive disease, due to a novel mutation in exon 5 of the CYP11A1 gene, which generated a truncated protein of 286 amino acids compared with wild-type protein that has 521 amino acids (W286X). Although unrelated, both parents are carriers. Mitochondrial protein import analysis of the mutant CYP11A1 in steroidogenic MA-10 cells showed that the protein is imported in a similar fashion as observed for the wild-type protein and was cleaved to a shorter fragment. However, mutant’s activity was 10% of that obtained for the wild-type protein in non-steroidogenic COS-1 cells. In a patient of Mexican descent, a homozygous CYP11A1 mutation caused CAH, suggesting that this disease is not geographically restricted even in a homogeneous population.

Learning points:

  • Novel mutation in CYP11A1 causes CAH;

  • This is a pure population from Central Mexico;

  • Novel mutation created early truncated protein.

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J Rajkanna Department of Endocrinology, Peterborough City Hospital, Bretton Gate, Peterborough, PE3 9GZ, UK

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S Tariq Department of Endocrinology, Peterborough City Hospital, Bretton Gate, Peterborough, PE3 9GZ, UK

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S O Oyibo Department of Endocrinology, Peterborough City Hospital, Bretton Gate, Peterborough, PE3 9GZ, UK

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Summary

Gonadotrophin therapy with human chorionic gonadotrophin and recombinant FSH is indicated for use in men with reduced spermatogenesis due to hypogonadotrophic hypogonadism (HH). Patients require regular monitoring for side effects and desired response to treatment. We present a man with HH, azoospermia and a history of previous anabolic steroid usage who had undergone gonadotrophin therapy, had subsequently achieved conception and has now fathered a child.

Learning points

  • In total, 15% of couples do not achieve pregnancy within 1 year and seek medical treatment for infertility: male factors contribute to 50% of these.

  • The evaluation of male infertility should include a full history and examination, an endocrine profile and a quality-controlled semen analysis.

  • HH with defective spermatogenesis is an important cause of male infertility in a small percentage of cases.

  • Gonadotrophin therapy requires regular monitoring for side effects and desired response to treatment.

  • Any sustained rise in prostate specific antigen levels should prompt urological assessment for possible prostate biopsy.

  • A multidisciplinary approach is required for gonadotrophin therapy, especially if assisted fertilisation techniques are required once, spermatogenesis is achieved.

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Rossella Mazzilli Andrology Unit, Department of Clinical and Molecular Medicine, Sant'Andrea Hospital, University of Rome “Sapienza”, Via di Grottarossa 103500189, Rome, Italy

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Michele Delfino Andrology Unit, Department of Clinical and Molecular Medicine, Sant'Andrea Hospital, University of Rome “Sapienza”, Via di Grottarossa 103500189, Rome, Italy

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Jlenia Elia Andrology Unit, Department of Clinical and Molecular Medicine, Sant'Andrea Hospital, University of Rome “Sapienza”, Via di Grottarossa 103500189, Rome, Italy

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Francesco Benedetti Andrology Unit, Department of Clinical and Molecular Medicine, Sant'Andrea Hospital, University of Rome “Sapienza”, Via di Grottarossa 103500189, Rome, Italy

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Laura Alesi Genetics Unit, Department of Clinical and Molecular Medicine, Sant'Andrea Hospital, University of Rome “Sapienza”, Via di Grottarossa 103500189, Rome, Italy

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Luciana Chessa Genetics Unit, Department of Clinical and Molecular Medicine, Sant'Andrea Hospital, University of Rome “Sapienza”, Via di Grottarossa 103500189, Rome, Italy

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Fernando Mazzilli Andrology Unit, Department of Clinical and Molecular Medicine, Sant'Andrea Hospital, University of Rome “Sapienza”, Via di Grottarossa 103500189, Rome, Italy

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Summary

We report the case of a 19-year-old boy, presenting several congenital malformations (facial dysmorphisms, cardiac and musculoskeletal abnormalities), mental retardation, recurrent respiratory infections during growth and delayed puberty. Although previously hospitalised in other medical centres, only psychological support had been recommended for this patient. In our department, genetic, biochemical/hormonal and ultrasound examinations were undertaken. The karyotype was 49,XXXXY, a rare aneuploidy with an incidence of 1/85 000–100 000, characterised by the presence of three extra X chromosomes in phenotypically male subjects. The hormonal/biochemical profile showed hypergonadotropic hypogonadism, insulin resistance and vitamin D deficiency. The patient was then treated with testosterone replacement therapy. After 12 months of treatment, we observed the normalisation of testosterone levels. There was also an increase in pubic hair growth, testicular volume and penis size, weight loss, homeostatic model assessment index reduction and the normalisation of vitamin D values. Moreover, the patient showed greater interaction with the social environment and context.

Learning points

  • In cases of plurimalformative syndrome, cognitive impairment, recurrent infections during growth and, primarily, delayed puberty, it is necessary to ascertain as soon as possible whether the patient is suffering from hypogonadism or metabolic disorders due to genetic causes. In our case, the diagnosis of hypogonadism, and then of 49,XXXXY syndrome, was unfortunately made only at the age of 19 years.

  • The testosterone replacement treatment, even though delayed, induced positive effects on: i) development of the reproductive system, ii) regulation of the metabolic profile and iii) interaction with the social environment and context.

  • However, earlier and timely hormonal replacement treatment could probably have improved the quality of life of this subject and his family.

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Avinash Suryawanshi Department of Endocrinology and Metabolism, Concord Repatriation General Hospital, Concord, New South Wales, 2139, Australia
Concord Clinical School, The University of Sydney, Sydney, New South Wales, 2139, Australia

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Timothy Middleton Department of Endocrinology and Metabolism, Concord Repatriation General Hospital, Concord, New South Wales, 2139, Australia
Concord Clinical School, The University of Sydney, Sydney, New South Wales, 2139, Australia

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Kirtan Ganda Department of Endocrinology and Metabolism, Concord Repatriation General Hospital, Concord, New South Wales, 2139, Australia
Concord Clinical School, The University of Sydney, Sydney, New South Wales, 2139, Australia

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Summary

X-linked adrenoleukodystrophy (X-ALD) is a rare genetic condition caused by mutations in the ABCD1 gene that result in accumulation of very long chain fatty acids (VLCFAs) in various tissues. This leads to demyelination in the CNS and impaired steroidogenesis in the adrenal cortex and testes. A 57-year-old gentleman was referred for the assessment of bilateral gynaecomastia of 6 months duration. He had skin hyperpigmentation since 4 years of age and spastic paraparesis for the past 15 years. Physical examination findings included generalised hyperpigmentation (including skin, buccal mucosa and palmar creases), blood pressure of 90/60 mmHg, non-tender gynaecomastia and bilateral hypoplastic testes. Lower limb findings were those of a profoundly ataxic gait associated with significant paraparesis and sensory loss. Primary adrenal insufficiency was confirmed and investigations for gynaecomastia revealed normal testosterone with mildly elevated luteinising hormone level and normal prolactin. The combination of primary adrenal insufficiency (likely childhood onset), partial testicular failure (leading to gynaecomastia) and spastic paraparesis suggested X-ALD as a unifying diagnosis. A serum VLCFA panel was consistent with X-ALD. Subsequent genetic testing confirmed the diagnosis. Treatment with replacement doses of corticosteroid resulted in improvement in blood pressure and increased energy levels. We have reported the case of a 57-year-old man with a very late diagnosis of X-ALD manifested by childhood onset of primary adrenal insufficiency followed by paraparesis and primary hypogonadism in adulthood. Thus, X-ALD should be considered as a possibility in a patient with non-autoimmune primary adrenal insufficiency and neurological abnormalities.

Learning points

  • Adult patients with X-ALD may be misdiagnosed as having multiple sclerosis or idiopathic spastic paraparesis for many years before the correct diagnosis is identified.

  • Screening for X-ALD with a VLCFA panel should be strongly considered in male children with primary adrenal insufficiency and in male adults presenting with non-autoimmune primary adrenal insufficiency.

  • Confirmation of a genetic diagnosis of X-ALD can be very useful for a patient's family as genetic testing enables detection of pre-symptomatic female heterozygotes who can then be offered pre-natal testing to avoid transmission of the disease to male offsprings.

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Marinos C Makris First Surgical Department of General Hospital of Athens ‘Georgios Gennimatas’, Alpha Institute of Biomedical Sciences (AIBS), Department of Pathology, Mesogeion 154, Athens 15669, Greece
First Surgical Department of General Hospital of Athens ‘Georgios Gennimatas’, Alpha Institute of Biomedical Sciences (AIBS), Department of Pathology, Mesogeion 154, Athens 15669, Greece

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Konstantinos C Koumarelas First Surgical Department of General Hospital of Athens ‘Georgios Gennimatas’, Alpha Institute of Biomedical Sciences (AIBS), Department of Pathology, Mesogeion 154, Athens 15669, Greece

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Apostolos S Mitrousias First Surgical Department of General Hospital of Athens ‘Georgios Gennimatas’, Alpha Institute of Biomedical Sciences (AIBS), Department of Pathology, Mesogeion 154, Athens 15669, Greece

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Giannos G Psathas First Surgical Department of General Hospital of Athens ‘Georgios Gennimatas’, Alpha Institute of Biomedical Sciences (AIBS), Department of Pathology, Mesogeion 154, Athens 15669, Greece

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Athanasios Mantzioros First Surgical Department of General Hospital of Athens ‘Georgios Gennimatas’, Alpha Institute of Biomedical Sciences (AIBS), Department of Pathology, Mesogeion 154, Athens 15669, Greece

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Stratigoula P Sakellariou First Surgical Department of General Hospital of Athens ‘Georgios Gennimatas’, Alpha Institute of Biomedical Sciences (AIBS), Department of Pathology, Mesogeion 154, Athens 15669, Greece

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Panagiota Ntailiani First Surgical Department of General Hospital of Athens ‘Georgios Gennimatas’, Alpha Institute of Biomedical Sciences (AIBS), Department of Pathology, Mesogeion 154, Athens 15669, Greece

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Evripides Yettimis First Surgical Department of General Hospital of Athens ‘Georgios Gennimatas’, Alpha Institute of Biomedical Sciences (AIBS), Department of Pathology, Mesogeion 154, Athens 15669, Greece

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Summary

Until now, less than ten cases of extra-adrenal chromaffin cell tumors have been reported to be localized to the spermatic cord area. All published studies report benign tumors with a diameter <2–3 cm and no invasion of the testis. In this article, we present one case of a giant malignant paraganglioma in the testis of a patient who had initially been operated for a giant mass in the scrotum. The mass developed in approximately 4 months. This is the first study reporting the following findings: i) paraganglioma was found exclusively in the testis, invading the testicle and not the spermatic cord, ii) it was malignant with lung metastasis, and iii) its size was 17.5 cm×10 cm×9.5 cm. We present the first – giant – malignant paraganglioma. Moreover, it is the first case report of a paraganglioma in the testis.

Learning points

  • This is the first study reporting the following findings:

  • Paraganglioma found exclusively in the testis, invading the testicle and not the spermatic cord.

  • It is malignant with lung metastasis.

  • It is of the size 17.5 cm×10 cm×9.5 cm.

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Carla Costa
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Cíntia Castro-Correia
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Alda Mira-Coelho Departments of Psychiatry

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Bessa Monteiro Paediatric Surgery, Hospital São João, Porto, Portugal

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Joaquim Monteiro Paediatric Surgery, Hospital São João, Porto, Portugal

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Ieuan Hughes Endocrinology and Diabetology Unit, Department of Paediatrics, Addenbrook's Hospital, University of Cambridge, Cambridge, UK

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Manuel Fontoura
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Summary

The development of male internal and external genitalia in an XY fetus requires a complex interplay of many critical genes, enzymes, and cofactors. The enzyme 17β-hydroxysteroid-dehydrogenase type 3 (17βHSD3) is present almost exclusively in the testicles and converts Delta 4-androstenodione (Δ4) to testosterone. A deficiency in this enzyme is rare and is a frequently misdiagnosed autosomal recessive cause of 46,XY, disorder of sex development. The case report is of a 15-year-old adolescent, who was raised according to female gender. At puberty, the adolescent had a severe virilization and primary amenorrhea. The physical examination showed a male phenotype with micropenis and blind vagina. The Tanner stage was A3B1P4, nonpalpable gonads. The karyotype revealed 46,XY. The endocrinology study revealed: testosterone=2.38 ng/ml, Δ4>10.00 ng/ml, and low testosterone/Δ4 ratio=0.23. Magnetic resonance imaging of the abdominal–pelvic showed the presence of testicles in inguinal canal, seminal vesicle, prostate, micropenis, and absence of uterus and vagina. The genetic study confirmed the mutation p.Glu215Asp on HSD17B3 gene in homozygosity. The dilemma of sex reassignment was seriously considered when the diagnosis was made. During all procedures the patient was accompanied by a child psychiatrist/psychologist. The teenager desired to continue being a female, so gonadectomy was performed. Estrogen therapy and surgical procedure to change external genitalia was carried out. In this case, there was a severe virilization at puberty. It is speculated to be due to a partial activity of 17βHSD3 in the testicles and/or extratesticular ability to convert Δ4 to testosterone by 17βHSD5. Prenatal exposure of the brain to androgens has increasingly been put forward as a critical factor in gender identity development, but in this case the social factor was more important for the gender assignment.

Learning points

  • In this case, we highlight the late diagnosis, probably because the patient belongs to a poor family without proper primary medical care.

  • We emphasize the psychological and social aspects in the sex assignment decision.

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