[Panorama on congenital disorders of glycosylation (CDG): from 1980 to 2020]. / Anomalies congénitales de la glycosylation (CDG) - 1980-2020, 40 ans pour comprendre.

Glycosylation is an essential and complex cellular process where monosaccharides are added one by one onto an acceptor molecule, most of the time a protein or a lipid, so called glycoprotein or glycolipid. This cellular process is found in every living organism and is tightly conserved during evolution. In human, if one of the glycosylation reactions is genetically impaired, Congenital Disorders of Glycosylation (CDG) appear. CDG are a growing family of more than a hundred genetic diseases. This review offers a panorama of CDGs from 1980 to the present, their discoveries, diagnoses and treatments.

TITLE: Anomalies congénitales de la glycosylation (CDG) - 1980-2020, 40 ans pour comprendre. ABSTRACT: La glycosylation est un processus cellulaire complexe conduisant à des transferts successifs de monosaccharides sur une molécule acceptrice, le plus souvent une protéine ou un lipide. Ce processus est universel chez tous les organismes vivants et est très conservé au cours de l'évolution. Chez l'homme, des perturbations survenant au cours d'une ou plusieurs réactions de glycosylation sont à l'origine de glycopathologies génétiques rares, appelées anomalies congénitales de la glycosylation ou congenital disorders of glycosylation (CDG). Cette revue propose de revisiter ces CDG, de 1980 à aujourd'hui, en présentant leurs découvertes, leurs diagnostics, leurs causes biochimiques et les traitements actuellement disponibles.

The turn to controls and the refinement of the concept of hereditary burden: The 1895 study of Jenny Koller.

Throughout the 19th century, many alienists reported the proportion of their patients who were "hereditarily burdened," meaning they had a positive family history for mental illness. The rates of such burden differed widely because different authors used divergent definition of illness and investigated different groups of relatives. Most importantly, no authors compared rates of burden with those seen in a nonpatient control group. The first such study in the history of psychiatric genetics was published in 1895, the doctoral dissertation of a Swiss physician Jenny Koller working under Auguste Forel. She obtained histories of a range of mental/neurologic disorders in the parents, aunts/uncles, grandparents and siblings of 370 hospitalized psychiatric patients and 370 controls. Rates of any hereditary burden were only modestly higher in cases (78%) than controls (59%). However, when examining individual syndromes, only major mental illness and eccentricities, but not apoplexy, nervous disorders or dementia, were more common in proband than control families. Furthermore, the rates of mental illness and eccentricities were substantially elevated in the first-degree relatives of cases versus controls but not in the second-degree relatives. Koller's study represented a major methodological advance in psychiatric genetics, helping to define which disorders coaggregated with major mental illness.

The dawn of the future: 30 years from the first biopsy of a human embryo. The detailed history of an ongoing revolution.

Following early studies showing no adverse effects, cleavage stage biopsy by zona drilling using acid Tyrode's solution, and removal of single blastomeres for preimplantation genetic testing (PGT) and identification of sex in couples at risk of X-linked disease, was performed by Handyside and colleagues in late 1989, and pregnancies reported in 1990. This method was later used for specific diagnosis of monogenic conditions, and a few years later also for chromosomal structural and/or numerical impairments, thereby establishing a valuable alternative option to prenatal diagnosis. This revolutionary approach in clinical embryology spread worldwide, and several other embryo biopsy strategies developed over three decades in a process that is still ongoing. The rationale of this narrative review is to outline the different biopsy approaches implemented across the years in the workflow of the IVF clinics that provided PGT: their establishment, the first clinical experiences, their downsides, evolution, improvement and standardization. The history ends with a glimpse of the future: minimally/non-invasive PGT and experimental embryo micromanipulation protocols. This grand theme review outlines a timeline of the evolution of embryo biopsy protocols, whose implementation is increasing worldwide together with the increasing application of PGT techniques in IVF. It represents a vade mecum especially for the past, present and upcoming operators and experts in this field to (re)live this history from its dawn to its most likely future.

An overview of 20 years of genetic studies in pheochromocytoma and paraganglioma.

Paragangliomas and pheochromocytomas (PPGL) are rare neuroendocrine tumours characterized by a strong genetic determinism. Over the past 20 years, evolution of PPGL genetics has revealed that around 40% of PPGL are genetically determined, secondary to a germline mutation in one of more than twenty susceptibility genes reported so far. More than half of the mutations occur in one of the SDHx genes (SDHA, SDHB, SDHC, SDHD, SDHAF2), which encode the different subunits and assembly protein of a mitochondrial enzyme, succinate dehydrogenase. These susceptibility genes predispose to early forms (VHL, RET, SDHD, EPAS1, DLST), syndromic (RET, VHL, EPAS1, NF1, FH), multiple (SDHD, TMEM127, MAX, DLST, MDH2, GOT2) or malignant (SDHB, FH, SLC25A11) PPGL. The discovery of a germline mutation in one of these genes changes the patient's follow-up and allows genetic screening of affected families and the presymptomatic follow-up of relatives carrying a mutation.

[Twenty years of on-site clinical genetics consultations for people with ASD]. / Vingt ans de consultations de génétique clinique sur site dans les hôpitaux de jour pour les personnes atteintes de troubles du spectre autistique de la région parisienne.

Despite advances in neurogenetics of autism spectrum disorders (ASD), many patients fail to be systematically investigated, owing to preconceived ideas, limited access to genetics facilities and inadequacy of consultations to children with behavioural problems. To improve access to services, we reversed the paradigm and delivered on-site genetics consultations to ASD children of Greater Paris day care hospitals and specialized institutions. Since 1998, an ambulatory medical genetics team has been in operation, offering on-site consultations and services to patients and relatives in their usual environment. Because the mobile medical genetics unit operates under the umbrella of a university hospital, service laboratories were shared, including molecular cytogenetics and next generation sequencing (NGS). For the past 20 years, 502 patients from 26 institutions benefited from on-site consultations and genetics services in their usual environment. Less than 1 % of parents declined the offer. Previously undiagnosed genetics conditions were recognized in 71 ASD children, including pathogenic CNV variants (34/388 : 8.8 ; de novo : 19, inherited : 4), Fragile X (4/312 : 1.3 %) and deleterious variants in disease causing genes (33/141 ; 23.4 % : de novo : 23 ; inherited : 10, including 5 X-linked and 5 compound heterozygote mutations). Brain MRI were possible in 347 patients and 42 % were considered abnormal (146/347). All diagnosed patients presented atypical/syndromic ASD with moderate to severe intellectual disability. Thanks to such flexible organisation, a considerable number of missed consultations were tracked and families first benefited from medical genetics services. Owing to constraints imposed by behavioural problems in ASD, we suggest considering on-site genetics services to implement standard of care and counteract the loss of chance to patients and relatives.

TITLE: Vingt ans de consultations de génétique clinique sur site dans les hôpitaux de jour pour les personnes atteintes de troubles du spectre autistique de la région parisienne. ABSTRACT: Malgré les avancées de la recherche, un grand nombre de patients atteints de troubles du spectre autistique (TSA) n'ont pas accès aux explorations aujourd'hui disponibles, du fait d'idées reçues, de l'insuffisance des structures à même de les explorer et de l'inadaptation des consultations hospitalières à leurs troubles du comportement. Pour améliorer l'accès aux soins et au progrès des connaissances, nous avons inversé le paradigme et offrons depuis 20 ans des consultations de génétique clinique sur site dans les hôpitaux de jour et les institutions spécialisées de la région parisienne. Depuis 1998, une équipe mobile de génétique médicale propose aux patients et à leurs familles des consultations dans leur environnement habituel. L'unité mobile opère sous l'égide de l'hôpital universitaire Necker Enfants-Malades, qui leur donne accès aux services de biochimie, de cytogénétique moléculaire et de séquençage de nouvelle génération (NGS). En vingt ans, 502 patients appartenant à 26 institutions ont bénéficié de consultations sur site et d'un accès aux plateformes de génétique moléculaire. Moins de 1 % des parents ont décliné la proposition. Des affections génétiques ont été identifiées chez 71 patients présentant un TSA : anomalies cytogénétiques causales (34/388 : 8,8 % ; de novo : 19, héritées : 4), X Fragile (4/312 : 1,3 %) et mutations monogéniques reconnues responsables de TSA (33/141 ; 23,4 % : de novo : 23 ; héritées : 10, dont 5 liées à l'X et 5 récessives autosomiques). L'IRM cérébrale a été possible chez 347 patients et considérée comme anormale chez 42 % d'entre eux (146/347). Tous les patients diagnostiqués présentaient un TSA atypique ou syndromique, avec déficience intellectuelle modérée à sévère. Grâce à ce mode d'intervention, un grand nombre de consultations manquantes ont été rattrapées et les familles ont pu bénéficier d'une consultation de génétique. Eu égard aux contraintes imposées par les troubles du comportement dans les TSA, les consultations sur site constituent, pour les patients et leurs apparentés, un moyen d'améliorer l'accès aux soins et de réduire le risque de méconnaissance d'une pathologie organique à présentation psychiatrique.

How diseases became "genetic".

This article examines the origins of the term "genetic disease." In the late 19 and early 20th century, an earlier idea that diseases that occur in families reflect a vague familiar "predisposition" was replaced by the view that such diseases have specific causes, while Mendelian genetics provided then clues to the patterns of their transmission. The genetictisation of inborn pathologies took a decisive turn with the redefinition, in 1959, of Down syndrome as a chromosomal anomaly, then the development of tests for the diagnosis of other hereditary pathologies. At that time, geneticists distinguished "hereditary" diseases that run in families, from "genetic" conditions that are the result of new mutations during the production of egg and sperm cells. In the latter case, the inborn impairment is produced by an anomaly in the genetic material of the cell, but is not hereditary, because it is not transmitted from one or both parents. In the late 20th and early 21st century, new genomic technologies blurred the distinction between hereditary and genetic impairments, extended the concept of genetic disease, and modified the experience of people living with such a disease.

How diseases became "genetic" / Como as doenças se tornaram "genéticas"

Abstract This article examines the origins of the term "genetic disease." In the late 19 and early 20th century, an earlier idea that diseases that occur in families reflect a vague familiar "predisposition" was replaced by the view that such diseases have specific causes, while Mendelian genetics provided then clues to the patterns of their transmission. The genetictisation of inborn pathologies took a decisive turn with the redefinition, in 1959, of Down syndrome as a chromosomal anomaly, then the development of tests for the diagnosis of other hereditary pathologies. At that time, geneticists distinguished "hereditary" diseases that run in families, from "genetic" conditions that are the result of new mutations during the production of egg and sperm cells. In the latter case, the inborn impairment is produced by an anomaly in the genetic material of the cell, but is not hereditary, because it is not transmitted from one or both parents. In the late 20th and early 21st century, new genomic technologies blurred the distinction between hereditary and genetic impairments, extended the concept of genetic disease, and modified the experience of people living with such a disease.

Resumo O presente artigo tem o objetivo de examinar as origens do termo "doença genética. No final do século XIX e início do XX, a vaga ideia que a doença manifesta entre familiares refletia uma "predisposição" familiar, foi substituída pela visão que essas doenças possuem causas específicas, enquanto a genética mendeliana forneceu as pistas para os padrões de transmissão da doença. A genética das patologias congênitas deu uma guinada decisiva, em 1959, com a redefinição da Síndrome de Down como uma anomalia cromossômica e, depois, com o desenvolvimento de testes para o diagnóstico de outras patologias hereditárias. Naquela época, os geneticistas distinguiam doenças "hereditárias" como aquelas que acometiam os elementos de uma família, de condições "genéticas" que são o resultado de novas mutações ocorridas durante a produção dos óvulos e espermatozoides. Neste último caso, a deficiência inata é causada por uma anomalia do material genético da célula, porque não é transmitida por qualquer um ou ambos os pais. No final do século XX e início do XXI, as novas tecnologias genômicas obscureceram a distinção entre deficiências hereditária e a genética, estenderam o conceito da doença genética e modificaram a experiência das pessoas que vivem com esse tipo de doença.

Direct-to-Consumer Testing 2.0: Emerging Models of Direct-to-Consumer Genetic Testing.

Direct-to-consumer (DTC) genetic testing emerged in the early 2000s as a means of allowing consumers to access information on their genetics without the involvement of a physician. Although early models of DTC were popular with consumers, they were controversial in medical and regulatory circles. In this article, we trace the history of DTC genetic testing, discuss its regulatory implications, and describe the emergence of a new hybrid model we call DTC 2.0.

Screening for fetal chromosomal and subchromosomal disorders.

Screening for fetal chromosomal disorders has evolved greatly over the last four decades. Initially, only maternal age-related risks of aneuploidy were provided to patients. This was followed by screening with maternal serum analytes and ultrasound markers, followed by the introduction and rapid uptake of maternal plasma cell-free DNA-based screening. Studies continue to demonstrate that cfDNA screening for common aneuploidies has impressive detection rates with low false-positive rates. The technology continues to push the boundaries of prenatal screening as it is now possible to screen for less common aneuploidies and subchromosomal disorders. The optimal method for incorporating cfDNA screening into existing programs continues to be debated. It is important that obstetricians understand the biological foundations and limitations of this technology and provide patients with up-to-date information regarding cfDNA screening.

Newborn screening: a review of history, recent advancements, and future perspectives in the era of next generation sequencing.

PURPOSE OF REVIEW: The purpose of this review is to summarize the development and recent advancements of newborn screening. RECENT FINDINGS: Early initiation of medical care has modified the outcome for many disorders that were previously associated with high morbidity (such as cystic fibrosis, primary immune deficiencies, and inborn errors of metabolism) or with significant neurodevelopmental disabilities (such as phenylketonuria and congenital hypothyroidism). The new era of mass spectrometry and next generation sequencing enables the expansion of the newborn screen panel, and will help to address technical issues such as turnaround time, and decreasing false-positive and false-negative rates for the testing. SUMMARY: The newborn screening program is a successful public health initiative that facilitates early diagnosis of treatable disorders to reduce long-term morbidity and mortality.