A five-generation family with sacral agenesis and spina bifida: possible similarities with the mouse T-locus

Towards clinical applications of in vitro-derived axial progenitors

The production of the tissues that make up the mammalian embryonic trunk takes place in a head-tail direction, via the differentiation of posteriorly-located axial progenitor populations. These include bipotent neuromesodermal progenitors (NMPs), which generate both spinal cord neurectoderm and presomitic mesoderm, the precursor of the musculoskeleton. Over the past few years, a number of studies have described the derivation of NMP-like cells from mouse and human pluripotent stem cells (PSCs). In turn, these have greatly facilitated the establishment of PSC differentiation protocols aiming to give rise efficiently to posterior mesodermal and neural cell types, which have been particularly challenging to produce using previous approaches. Moreover, the advent of 3-dimensional-based culture systems incorporating distinct axial progenitor-derived cell lineages has opened new avenues toward the functional dissection of early patterning events and cell vs non-cell autonomous effects. Here, we provide a brief overview of the applications of these cell types in disease modelling and cell therapy and speculate on their potential uses in the future.

Understanding axial progenitor biology in vivo and in vitro

The generation of the components that make up the embryonic body axis, such as the spinal cord and vertebral column, takes place in an anterior-to-posterior (head-to-tail) direction. This process is driven by the coordinated production of various cell types from a pool of posteriorly-located axial progenitors. Here, we review the key features of this process and the biology of axial progenitors, including neuromesodermal progenitors, the common precursors of the spinal cord and trunk musculature. We discuss recent developments in the in vitro production of axial progenitors and their potential implications in disease modelling and regenerative medicine.

Comparison of inherited neural tube defects in companion animals and livestock

Neural tube defects (NTDs) are congenital malformations resulting from the improper or incomplete closure of the neural tube during embryonic development. A number of similar malformations of the protective coverings surrounding the central nervous system are also often included under this umbrella term, which may not strictly fit this definition. A range of NTD phenotypes exist and have been reported in humans and a wide range of domestic and livestock species. In the veterinary literature, these include cases of anencephaly, encephalocele, dermoid sinus, spina bifida, and craniorachischisis. While environmental factors have a role, genetic predisposition may account for a significant part of the risk of NTDs in these animal cases. Studies of laboratory model species (fish, birds, amphibians, and rodents) have been instrumental in improving our understanding of the neurulation process. In mice, over 200 genes that may be involved in this process have been identified and variant phenotypes investigated. Like laboratory mouse models, domestic animals and livestock species display a wide range of NTD phenotypes. They remain, however, a largely underutilized population and could complement already established laboratory models. Here we review reports of NTDs in companion animals and livestock, and compare these to other animal species and human cases. We aim to highlight the potential of nonlaboratory animal models for mutation discovery as well as general insights into the mechanisms of neurulation and the development of NTDs.

Importance of gene-environment interactions in the etiology of selected birth defects

It is generally understood that both genetic and environmental factors contribute to the highly complex etiology of structural birth defects, including neural tube defects, oral clefts and congenital heart defects, by disrupting highly regulated embryonic developmental processes. The intrauterine environment of the developing embryo/fetus is determined by maternal factors such as health/disease status, lifestyle, medication, exposure to environmental teratogens, as well as the maternal genotype. Certain genetic characteristics of the embryo/fetus also predispose it to developmental abnormalities. Epidemiologic and animal studies conducted over the last few decades have suggested that the interplay between genes and environmental factors underlies the etiological heterogeneity of these defects. It is now widely believed that the study of gene-environment interactions will lead to better understanding of the biological mechanisms and pathological processes that contribute to the development of complex birth defects. It is only through such an understanding that more efficient measures will be developed to prevent these severe, costly and often deadly defects. In this review, we attempt to summarize the complex clinical and experimental literature on current hypotheses of interactions between several select environmental factors and those genetic pathways in which they are most likely to have significant modifying effects. These include maternal folate nutritional status, maternal diabetes/obesity-related conditions, and maternal exposure to selected medications and environmental contaminants. Our goal is to highlight the potential gene-environment interactions affecting early embryogenesis that deserve comprehensive study.

[Degree of genetic homozygosity among patients with spinal dysraphia]

INTRODUCTION

Our study of genetic homozygosity degree includes an analysis of the presence, distribution and individual combination of 15 selected genetically controlled morphophysiological traits in the sample of patients with spinal dysraphia (N=35) and in the control-healthy group (N=50).

OBJECTIVE

Assuming that spinal dysraphia is a genetically controlled disease, we made a hypothesis that an increased homozygosity level, as well as the changed variability among patients, could be a population-genetic parameter for the prediction of the illness.

METHOD

Taking into consideration our experience, as well as the experience of numerous scientists who studied the nature of the inheritance of mono- and oligo-genically controlled qualitative traits, we applied a methodology to estimate the proportion of such homozygously recessive characters (HRC-test,).

RESULTS

This population-genetic study did not only show a statistically significant difference of the mean values of genetic homozygosity (SD 4.8 +/- 0.3; control 3.5 +/- 0.3), but of the differences in the type of distribution too, as well as the differences in the presence of certain individual combinations of such traits.

CONCLUSION

Due to the fact that those genes which control such qualitative recessive traits are distributed in different human chromosomes, being their visible markers, this could indicate that degrees of genetic homozygosity are ostensibly greater in a sample of patients with spinal dysraphia compared to the control group of individuals.

Epidemiology of neural tube defects

The epidemiological investigation of the common open neural tube defects (NTDs), anencephaly, and spina bifida, has a long history. The most significant finding from these past studies of NTDs was the identification of the protective effect of maternal, periconceptional supplementation with folic acid. Fortuitously, the association between folic acid and NTDs became widely accepted in the early 1990s, at a time when genetic association studies of complex traits were becoming increasingly feasible. The confluence of these events has had a major impact on the direction of epidemiological, NTD research. Association studies to evaluate genes that may influence the risk of NTDs through their role in folate-related processes, or through other metabolic or developmental pathways are now commonplace. Moreover, the study of genetic as well as non-genetic, factors that may influence NTD risk through effects on the nutrient status of the mother or embryo has emerged as a major research focus. Research efforts over the past decade indicate that gene-gene, gene-environment, and higher-order interactions, as well as maternal genetic effects influence NTD risk, highlighting the complexity of the factors that underlie these conditions. The challenge for the future is to design studies that address these complexities, and are adequately powered to detect the factors or combination of factors that influence the development of NTDs.

Mapping a chromosomal locus for valproic acid-induced exencephaly in mice

Human neural tube defects (NTDs) are among the most common congenital defects. They have a highly heterogeneous etiology, and, in addition to those seen in association with genetic syndromes, there are also NTDs induced by pharmaceutical compounds in utero, such as the widely used anti-epileptic drug valproic acid (VPA). Although familial studies have suggested a genetic contribution to VPA-induced NTDs, this trait has not been adequately studied, nor have the responsible genetic factors been identified. We generated a series of mouse crosses and backcrosses using the highly inbred SWV/Fnn and C57BL/6J strains, in order to identify possible chromosomal loci contributing to VPA sensitivity. When exposed to a high dose of sodium VPA (600 mg/kg) via maternal intraperitoneal injection on gestational day E8.5, the fetuses manifested exencephaly in a strain-dependent manner. Our data show an autosomal recessive trait, plus a gender-related effect or an overall X-Chromosome (Chr) effect, as being primarily responsible for determining sensitivity to VPA-induced exencephaly. Genome scanning and further linkage analysis of 131 exencephalic backcross fetuses identified a major locus linked to D7Mit285 (p < 2 x 10(-6)), exceeding the threshold for significant linkage. These results suggest a major chromosomal locus associated with the sensitivity to VPA-induced exencephaly in mice.

Genetic dissection of hyperthermia-induced neural tube defects in mice

BACKGROUND

Maternal hyperthermia has been shown to induce neural tube defects (NTD) in humans and in experimental animal systems. We report the first genetic dissection of maternal hyperthermia-induced NTD in mice.

METHODS

After maternal exposure on E8.5 to 43 degrees C water bath for 10 min, we observed exencephaly frequencies among E15.5-17.5 fetuses from the following crosses and backcrosses, SWV/Fnn(SWV)xSWV, C57BL/6J(C57)xC57, SWVxC57 (F1), F1xSWV and SWVxF1.

RESULTS

The fetuses with maternal hyperthermia exposure developed exencephaly in a strain-dependent manner and the exencephaly frequencies among the above crosses were 46.2, 14.3, 13.6, 11.3, and 27.0%, respectively, expressed over total live fetuses. The fetal death rates were 47.3, 24.6, 37.1, 4.3, and 35.5%, respectively, expressed over total implants.

CONCLUSION

The data demonstrate that a single fetal genetic locus, plus a maternal effect, have likely caused the strain differences in the susceptibility to hyperthermia-induced exencephaly. A maternal effect alone may have caused the higher prenatal mortality rates in the SWVxF1 cross versus the reciprocal cross. Analysis of gender ratios among those affected from these crosses excludes an X- or Y-linked effect in causing the higher numbers of affected females.

Autosomal dominant sacral agenesis: Currarino syndrome

Autosomal dominant sacral agenesis is characterised by a partial agenesis of the sacrum typically involving sacral vertebrae S2-S5 only. Associated features include anorectal malformation, a presacral mass, and urogenital malformation. Together, these features have been defined as the Currarino syndrome. Recently, HLXB9 has been identified as the major causative gene in Currarino syndrome allowing identification of asymptomatic heterozygotes. In this review, we have performed an analysis of medical publications, and our own additional cases, to identify the range of malformations and complications that occur. We have also estimated risks of malformation in heterozygotes by using Weinburg's proband method on families personally known to us in order to provide accurate genetic counselling information.

Neural crest anomaly syndromes in children with spina bifida

A hereditary contribution to the etiology of neural tube defects (NTDs) has been suggested by clinical studies and animal models. To evaluate the hypothesis that common genes are important for both neural tube defects and neural crest anomalies, we examined children with developmental abnormalities of the spinal cord for anomalies of neural crest-derived structures. Neural crest anomalies, particularly auditory and pigmentary disorders, were identified and classified according to inheritance and type of anomaly. Of the 515 children screened, 44 (8.5%) had neural crest anomalies, 20 (3.9%) of which were apparently familial. Another 19 (3.7%) families had neural crest anomalies in two or more close relations, but the NTD subject was unaffected. Sixteen (3.1%) children with NTDs had a recognizable syndrome, including nine (1.7%) with a subtype of the Waardenburg syndromes. The coincidence of familial neural crest anomaly syndromes in subjects with spina bifida implies that defects in genes underlying neural crest development may contribute to the etiology of neural tube defects in a fraction of cases. The rate of anomalies and familial syndromes of neural crest-derived structures must be assessed in an adequate control sample to evaluate whether or not these abnormalities constitute risk factors for NTDs.

Closed spinal dysraphism: a review on diagnosis and treatment in infancy

This article reviews the clinical presentation, pathophysiology, diagnostic strategies, and therapeutic management of closed spinal dysraphism in infancy. Four groups of symptoms are distinguished: (1) cutaneous abnormalities, (2) lower motor neuron dysfunction due to congenital spinal and nerve root abnormalities, (3) upper motor neuron dysfunction due to tethering of the spinal cord, and (4) symptoms caused by associated malformations. Guidelines are proposed concerning timing and type of diagnostic investigations in infancy. This essentially encompasses a neurological assessment, including spinal ultrasonography and nuclear magnetic resonance imaging of the spine and the brain, and a urological assessment, including ultrasonography of kidneys and bladder, cystourethrography and a urodynamic study. As to the tethered cord syndrome it is concluded that first, already in infancy, a progressive neurological dysfunction can be detected; second, surgical untethering should be performed only upon appearance of upper motor neuron signs or upon progression of lower motor neuron signs. Despite its frequently asymptomatic course, the diagnosis of a congenital lumbosacral lipoma, and in the more general sense, of a closed spinal dysraphism, implies a periodic, multidisciplinary follow-up for life.

Isolated sacral agenesis in a fetus monosomic for 7q36.1-->qter

A fetus with severe sacral agenesis and intrauterine growth retardation, ascertained at prenatal diagnosis, was found to be carrying an unbalanced form of a paternal balanced reciprocal translocation (7;19)(q36.1;q13.43), resulting in functional monosomy for 7q36.1-->qter. Necropsy confirmed that the fetus had isolated sacral agenesis type II. A critical region for autosomal dominant sacral agenesis has recently been mapped to the 7q36 region. This case provides further evidence for a sacral agenesis locus in this region and may help to refine the critical region further.

A gene for autosomal dominant sacral agenesis maps to the holoprosencephaly region at 7q36

Sacral agenesis is a rare disorder of uncertain incidence that has been reported in diverse populations. Although usually sporadic and most commonly associated with maternal diabetes, there is a hereditary form which may occur in isolation or with a presacral mass (anterior meningocele and/or presacral teratoma) and anorectal abnormalities, which constitute the Currarino triad (MIM 176450). The radiological hallmark of hereditary sacral agenesis is a hemi-sacrum (sickle-shaped sacrum) with intact first sacral vertebra. Bowel obstruction is the usual neonatal presentation, but, unlike other neural tube defects, adult presentation is not uncommon. The major pathology is confined to the pelvic cavity and may present as a space-occupying lesion or meningitis due to ascending infection. All recurrences in families have been compatible with autosomal dominant inheritance except for those associated with the isomerism gene at Xq24-q27.1 (ref. 3). Several associated cytogenetic defects have been reported, including 7q deletions. Previous studies failed to detect linkage to HLA markers, but we now present evidence for a location on 7q36. The same region also contains a gene for holoprosencephaly, an early malformation of the extreme rostral end of the neural tube.

Absence of linkage between familial neural tube defects and PAX3 gene

Neural tube defects (NTD) are among the most common and disabling birth defects. The aetiology of NTD is unknown and their genetics are complex. The majority of NTD cases are sporadic, isolated, nonsyndromic, and generally considered to be multifactorial in origin. Recently, PAX3 (formerly HuP2, the human homologue of mouse Pax-3), on chromosome 2q35-37, was suggested as a candidate gene for NTD because mutations of Pax-3 cause the mouse mutant Splotch (Sp), an animal model for human NTD. Mutations in PAX3 were also identified in patients with Waardenburg syndrome type 1 (WS1). At least eight patients with both WS1 and NTD have been described suggesting pleiotropy or a contiguous gene syndrome. Seventeen US families and 14 Dutch families with more than one affected person with NTD were collected and 194 people (50 affected) from both data sets were genotyped using the PAX3 polymorphic marker. The data were analysed using affecteds only linkage analysis. The lod scores were -7.30 (US), -3.74 (Dutch), and -11.04 (combined) at theta = 0.0, under the assumption of the autosomal dominant model. For the recessive model, the lod scores were -3.30 (US), -1.46 (Dutch), and -4.76 (combined) at theta = 0.0. Linkage between PAX3 and familial NTD was excluded to 9.9 cM on either side of the gene for the dominant model and to 3.63 cM on either side of the gene for the recessive model in the families studied. No evidence of heterogeneity was detected using the HOMOG program. Our data indicate that PAX3 is not a major gene for NTD.

Linkage analysis of a candidate locus (HLA) in autosomal dominant sacral defect with anterior meningocele

Sacral defect with anterior meningocele (SDAM) is a type of caudal dysgenesis. It is present at birth and becomes symptomatic later in life, usually because of obstructive labor in females, chronic constipation, rectal fistula and abscess, or meningitis. The inheritance is autosomal dominant. HLA has been implicated in caudal dysgenesis because of analogy with disorders of the T-locus complex, a tail length determining gene in mice which is linked to the major histocompatibility complex, H-2. Members of a 5-generation family with sacral defect and anterior meningocele (SDAM) were typed with polymorphic markers (dinucleotide repeats D6S89, D6S105, D6S109, and TCTE1) linked to HLA. Two-point and multipoint analysis exclude the HLA region as the location for the SDAM gene in this family.

Evidence for multi-site closure of the neural tube in humans

Four separate initiation sites for neural tube (NT) fusion have been demonstrated recently in mice and other experimental animals. We evaluated the question of whether the multisite model vs. the traditional single-site model of NT closure provided the best explanation for neural tube defects (NTDs) in humans. Evidence for segmental vs. continuous NT closure was obtained by review of our recent clinical cases of NTDs and previous medical literature. With the multi-site NT closure model, we find that the majority of NTDs can be explained by failure of fusion of one of the closures or their contiguous neuropores. We hypothesize that: Anencephaly results from failure of closure 2 for meroacranium and closures 2 and 4 for holoacranium. Spina-bifida cystica results from failure of rostral and/or caudal closure 1 fusion. Craniorachischisis results from failure of closures 2, 4, and 1. Closure 3 non-fusion is rare, presenting as a midfacial cleft extending from the upper lip through the frontal area ("facioschisis"). Frontal and parietal cephaloceles occur at the sites of the junctions of the cranial closures 3-2 and 2-4 (the prosencephalic and mesencephalic neuropores). Occipital cephaloceles result from incomplete membrane fusion of closure 4. In humans, the most caudal NT may have a 5th closure site involving L2 to S2. Closure below S2 is by secondary neurulation. Evidence for multi-site NT closure is apparent in clinical cases of NTDs, as well as in previous epidemiological studies, empiric recurrence risk studies, and pathological studies. Genetic variations of NT closures sites occur in mice and are evident in humans, e.g., familial NTDs with Sikh heritage (closure 4 and rostral 1), Meckel-Gruber syndrome (closure 4), and Walker-Warburg syndrome (2-4 neuropore, closure 4). Environmental and teratogenic exposures frequently affect specific closure sites, e.g., folate deficiency (closures 2, 4, and caudal 1) and valproic acid (closure 5 and canalization). Classification of NTDs by closure site is recommended for all studies of NTDs in humans.(ABSTRACT TRUNCATED AT 400 WORDS)

Pentalogy of Cantrell and associated midline anomalies: a possible ventral midline developmental field

Five cases of the Pentalogy of Cantrell (PC), ascertained through the Baltimore-Washington population-based study of infants with congenital cardiovascular malformations, represent a regional prevalence of 5.5/1 million liveborn infants for this disorder. Three of these patients had cleft lip with or without palate. Review of the reported literature of the Pentalogy of Cantrell and various combinations of the anomalies within the spectrum of this pentad suggests that the PC defines a specific midline ventral developmental field. Cleft lip with or without cleft palate and encephalocele tend to specifically associate with ventral midline anomalies within the spectrum of PC. These associations might either illustrate the previously observed tendency of specific occurrence of certain combinations of midline defects or represent defined subunits of the midline developmental field.

Sacrococcygeal dysgenesis association

In the malformation analysis of 445 patients ascertained only for a sacrococcygeal malformation, a new phenotype, the sacrococcygeal dysgenesis association (SDA), was delineated in 34%. In addition, sirenomelia patients were found in 12%, the VATER association in 27%, and 27% could not be classified. Heterogeneity in the patients with sacrococcygeal malformations was identified by the differences found in their associated malformations. SDA patients have a relatively small average number (3.3) of anomalies per patient as compared with 9.3 in sirenomelia and 6.2 in VATER patients. SDA abnormalities occurred to a significant degree only in 6 of 20 designated malformation categories (vertebral, rib, pelvic, lower limb, central nervous system [CNS], renal) in contrast to 17 in VATER and 18 in sirenomelia patients. The SDA vertebral malformation pattern also differed from that of VATER/sirenomelia patients as did the high sacrococcygeal agenesis:dysgenesis ratio and low thoracolumbar vertebrae and/or rib hypersegmentations. Most significantly, SDA patients had a large number of CNS anomalies and CNS-related dysfunctions of the urinary and distal intestinal tracts but no anatomic urinary or intestinal tract malformations. This contrasted sharply with the markedly increased occurrences of anatomic abnormalities in these body regions of the sirenomelia and VATER patients. Demographic data such as patient survival, twinning and, particularly, the high (28%) incidence of maternal diabetes in the SDA further support its differentiation from VATER/sirenomelia patients.

Chromosome 6q deletions: a report of two additional cases and a review of the literature

Here we report on two additional cases of distal 6q deletions with one case showing a terminal deletion of chromosome 6 (46,XY, del(6)(pter----q26:)) and one case showing an interstitial deletion of chromosome 6 (46,XY, del(6)(pter----q23::q25----qter)). The association of retinal abnormalities in 6q deletions is supported, and the additional manifestations of skin hyperextensibility, sacral abnormality, and imperforate anus are described.

Caudal regression syndrome and spondyloepiphyseal dysplasia in a 6-year-old child. A new syndrome?

A 6-year-old Algerian boy with "caudal regression syndrome" and spondylo-epiphyseal dysplasia is reported. We believe this represents a new malformation syndrome or a random association of two non-related entities.

Anorectal malformations with sacral bony abnormalities

A range of anorectal malformations with sacral bony abnormalities was found in members from three generations of two kindreds. The anorectal anomaly was low in all but one of the patients. Partial sacral agenesis was the main bony defect in one family, and meningomyelocele and spina bifida occulta were noted in the second. The inheritance pattern in these kinships is autosomal dominant. This may be a variant of caudal regression syndrome, which seems to be aetiologically heterogeneous.

Malformation syndromes: a review of mouse/human homology

The purpose of this paper is to review the known and possible homologies between mouse and human multiple congenital anomaly syndromes. By identifying single gene defects causing similar developmental abnormalities in mouse and man, comparative gene mapping can be carried out, and if the loci in mouse and man are situated in homologous chromosome segments, further molecular studies can be performed to show that the loci are identical. This paper puts forward tentative homologies in the hope that some will be investigated and shown to be true homologies at the molecular level, thus providing mouse models for complex developmental syndromes. The mouse malformation syndromes are reviewed according to their major gene effects. X linked syndromes are reviewed separately because of the greater ease of establishing homology for these conditions.

The molecular genetics of human chromosome 6

Chromosome 6 contains several clinically important markers as well as classical enzyme loci, proto-oncogenes, and a growing number of anonymous DNA restriction fragment length polymorphisms (RFLPs). It is also of unique interest because of the location of the major histocompatibility complex (MHC) on the short arm, at 6p21.3. The MHC is one of the most detailed areas of the human genetic map to date and many important diseases, some of a suspected autoimmune aetiology, are associated with it.

Neural tube defects and sex ratios

The sex ratio of 147 fetuses with presumed multifactorial neural tube defect (NTD) was studied. Overall, the ratio (males:females) was 0.73 with expected female excess. However, when the NTDs were subdivided according to the site of the lesion, the sex ratios varied. Total craniorachischisis, anencephaly with cervical spina bifida, holoacrania, and thoracic spina bifida showed a greater female excess than that overall; the sex ratio for meroacrania was close to unity, while that for low spinal lesions, particularly those involving the sacrum, showed an extreme bias towards males. These findings are related to the mode of formation of the neural tube. Females seem prone to defects of neurulation and males to defects in canalization. An explanation for these findings is suggested in possible sex differences in rate of early embryonic development.

Molecular approaches to developmental genetics and pathology

New insights into gene structure and expression and the observation that homeobox-containing genes, the t-complex, and oncogenes are expressed also in humans contribute to the understanding of normal and pathobiological mechanisms of embryonal and fetal development.

Neural tube defects: a review of human and animal studies on the etiology of neural tube defects

Although neural tube defects are a common congenital anomaly, their etiology is not known. Human studies have emphasized the pathology and epidemiology of the defects and suggest that in the majority of cases the etiology is multifactorial. Factors which appear possibly to be important are genetic predisposition, maternal illness, and fetal drug exposure. Animal studies have utilized naturally occurring neural tube defects and teratologically induced lesions. No animal model has been convincingly established as the equivalent of human neural tube defects. However, animal models have allowed investigation of the mechanisms of suggested human teratogens and determination of the pathogenesis of naturally occurring animal defects. Their most important contribution has been in furthering the understanding of the normal mechanisms of neural tube closure. It may be through this understanding that the etiology of human neural tube defects will be determined.

Craniofrontonasal dysplasia: clinical and genetic analysis

We have identified a case of craniofrontonasal dysplasia which demonstrates the potential lethality of this gene. Genetic analysis of this pedigree and nine others reveals that craniofrontonasal dysplasia does not follow a Mendelian mode of inheritance and may be a human mutation analogous to the T-locus of mice.

Complotypes, extended haplotypes, male segregation distortion, and disease markers

From our studies in Caucasian families of HLA, complement, and glyoxalase alleles have developed the concepts of the complotype and the extended haplotype. complotypes are clusters of the four genes for complement proteins encoded within the MHC designated (in arbitrary order) by their BF, C2, C4A, and C4B alleles. They are inherited in families and occur in populations as functionally single genetic units and exhibit linkage disequilibrium with HLA-B and HLA-DR alleles which are complotype, rather than complement gene allele, specific. In Caucasians, there are 10-12 common sets of HLA-B, DR, complotype sets that show significant linkage disequilibrium. These haplotypes constitute 25-30% of all MHC haplotypes in Caucasians. Because there is evidence for relative fixity of alleles on these chromosomes to an unknown extent beyond the HLA-B-DR interval, they have been called extended MHC haplotypes. It appears likely that it is these extended haplotypes that provide most of the known linkage disequilibrium pairs previously reported for MHC alleles as well as many of the known MHC allele-disease associations. The most common extended haplotype [HLA-B8, DR3, SC01], when it carries GLO2, is increased in type I diabetes mellitus and probably a number of other diseases, including gluten-sensitive enteropathy and membranoproliferative glomerulonephritis. In the families with these disorders studied by us, this haplotype exhibits male segregation distortion, a feature displayed by t-mutants found in wild mouse populations. This feature constitutes an important selective advantage for the chromosome and may contribute to the accumulation of susceptibility mutations for a variety of diseases.(ABSTRACT TRUNCATED AT 250 WORDS)

Genetic analysis of the T/t complex

The T/t-complex has held considerable interest for immunologists, primarily because of its close genetic linkage to the major histocompatibility complex (MHC) on mouse chromosome 17. This interest has been heightened recently with the discovery that the MHC is fully contained within the t-complex and that two regions of the MHC, Qa and K, contain t-lethal genes. For a long time, T/t has been an enigmatic system, mainly because classical genetic analysis was not possible. Here the system is defined, recent information is presented, and our understanding of the mouse data to available information about the human MHC is correlated.

An association of caudal malformations arising from a defect in the "axial mesoderm" developmental field

We have studied two newborn infants with a remarkable genital malformation, failure of urethral development with enormous bladder distension, atresia of the distal hindgut, vertebral abnormalities, and compression deformities. This is a pattern of anomalies similar to, and probably an extension of, the association of female pseudohermaphroditism and other anomalies (FPA) described by Lubinsky [Am J Med Genet 6:123-136, 1980]. We propose that its pathogenesis involves a defect expressed in mesoderm, especially caudal mesoderm. We offer some speculation on what might be its nature, with particular reference to the theory of cell surface molecules having a role in morphogenesis. We apply the concept of the developmental field to provide a clarifying perspective.

Caudal deficiency and asplenia anomalies in sibs

The caudal deficiency and asplenia anomalies have been described separately in children. Two sibs with these two entities are described. Only another similar case, with caudal deficiency and polysplenia anomalies was found in the literature. It is possible that this association could be a new syndromic entity. An autosomal recessive mode of inheritance is suggested.

Sibs of probands with neural tube defects--a study in the Federal Republic of Germany

Data for the risk of neural tube defects in sibs of affected children are needed for genetic counselling, for decision on prenatal studies, and for planning of preventive measures. Data have been reported from various populations but were lacking for Germany. This study presents data on the siblings of 240 index patients in the Western part of the Federal Republic of Germany. The prevalence among sibs of affected individuals was found to be 2.6%. This figure agrees well with reports from other countries in Continental Europe and the United States, and fits the expectation of lower recurrence risks in low incidence populations.

Possible causal heterogeneity in spina bifida cystica

A study was performed to determine whether causal heterogeneity can be demonstrated among the nonsyndromal spina bifida cysticas based on the vertebral level of the defect. Two groups were compared, probands with defects at or above T 11, likely representing defects of neuralization, and probands with defects at or below T 12, likely defects of canalization. Differences between the two groups were found with respect to reproductive history and occurrence of other malformations. A high degree of concordance for the type of defect among affected sib pairs was also observed. These findings indicate that there is probably heterogeneity within the spina bifida cysticas based on the level of the defect.

HLA-DR locus and maternal-foetal relation

Antigen HLA-A, B sharing couples have been previously observed in abnormal pregnancies of unknown etiology. We have determined the HLA-A, B, C and DR antigens of 20 couples with recurrent spontaneous abortions (RSAs), 32 control couples and 100 normal controls. The results showed that in couples with more than two idiopathic repeated abortions, there is no significant increase in the HLA antigen sharing couples. But we were able to observe, in the affected couples, a significant increase in HLA-DR antigen sharing as regards the control couples. We also find a significant increase in the DR5 antigen, in both wives and husbands, in couples with repeated abortions of unknown etiology as previously described for the Dw5 antigen.

Central nervous system malformations in the Kraków region. II. Case control studies on the human leukocyte antigen genotype and haplotype frequencies

A case control study of human leukocyte antigen haplotypes was performed on a sample of 44 index families of children with central nervous system (CNS) malformation and 36 families of healthy newborn infants. HLA typing for antigens determined by loci A, B, and C was done on parents and offspring. The HLA genotypes were inferred from segregation in families and the HLA gene and haplotype frequencies were obtained by direct gene counting. Case-control comparison did not uncover significant differences at any HLA allele. The haploytype pattern in the group of index cases did not show association with CNS malformations. The HLA phenotype compatibility among the probands' and controls' parents was within the same range except for locus C where parents of children with neural tube defects (NTD) less frequently shared common HLA-C antigens. The segregation of paternal haploytypes showed significant deviation in the families of NTD infants.

The syndrome of caudal dysplasia: a review, including etiologic considerations and evidence of heterogeneity

The syndrome of caudal dysplasia (CDS) and the wide spectrum of associated skeletal and other anomalies are reviewed, and a further case of this disorder is presented. The syndrome of CDS should be distinguished from the familial forms of sacral dysgenesis, three forms of which are tentatively identified. Two of these usually involve some degree of "hemi-sacrum." The third is usually manifested as partial sacral agenesis with absent distal segments. All these familial types are probably genetic dominants, and none is associated with maternal diabetes. Usually CDS is not familial, but it often is associated with a tendency toward diabetes in the mother. The suggestion is advanced here that CDS is the result of a combination of two principal factors represented by (a) a maternal diabetic tendency and (b) separate nondiabetogenic genes. Determination of the human leucocyte antigen (HLA) haplotypes involved in CDS is suggested to investigate the possibility of genetically distinctive factors in this condition.

Major histocompatibility complex (MHC)-linked genes affecting development

Genes affecting growth and development which are linked to the major histocompatibility complex have been found in the mouse (t-complex) and in the rat (growth and reproduction complex, grc), and there is some evidence that they also exist in humans. The genes of the t-complex have different effects depending upon the specific combinations involved: skeletal and fertility abnormalities, complete or partial embryonic mortality, high transmission ratios (segregation distortion) in males, high level of linkage disequilibrium with H-2, and suppression of recombination over the adjacent portion of the chromosome. The grc in the homozygous state causes small body size, sterility in the male and reduced fertility in the female, partial embryonic mortality, and a high level of linkage disequilibrium with RT1. It also interacts epistatically with the heterozygous Tal (tail anomaly lethal) gene to cause complete embryonic death. Mice carrying t-haplotypes and rats carrying the grc have an antigen in the male germ cells which cross-reacts very strongly (t-antigen). Suggestive evidence for such genes in humans comes from (1) studies on the relationship between skeletal defects and HLA haplotypes; (2) the association of specific HLA and complement haplotypes with a high transmission ratio in males, linkage disequilibrium among certain HLA and complement specificities and suppression of recombination in some MHC haplotypes; and (3) the lack of homozygotes in an isolated inbreeding population of desert nomads (Kel Kummer Tuaregs). In addition, immunogenetic studies on couples having chronic spontaneous abortions suggest that there is an unusually high incidence of homozygosity for the HLA-D/DR and HLA-A loci in these couples, and this finding is consistent with the presence of linked loci which behave like t or grc.

Epidemiology and genetics of neural tube defects: an application of the Utah Genealogical Data Base

The distribution and prevalence of births with neural tube defects in Utah from 1940 to 1979 are analyzed with regard to prevalence rates, secondary sex ratios, seasonality, yearly rates, and time-space clustering. The overall prevalence rate of 1.00 per thousand live births is comparable to that of other populations in the western United States. Analysis of sex ratios indicates a substantially higher proportion of females than males. No significant secular trends or time-space clustering are observed. No seasonality is seen for spina bifida; however, the anencephaly cases are delivered more frequently in the early spring and fall months. Following linkage of the neural tube defect cases to the Utah Genealogical Data Base, application of the genealogical index method shows substantial familial clustering of the disease. The average inbreeding coefficient of the neural tube defect cases is not elevated over that of matched controls. The empirical recurrence risk for the disease is calculated to be 3%, and the heritability estimate is 70%. Likelihood analysis of pedigrees containing spina bifida occulta and spina bifida cystica indicates that they may segregate as an autosomal dominant trait with a penetrance of 75%.

Occurrence of neural tube defects among first-, second-, and third-degree relatives of probands: results of a United States study

Data on the occurrence of neural tube defects in first-, second-, and third-degree relatives of probands were collected in a United States study. The proportions of affected individuals were 3.2%, 0.5%, and 0.17% respectively. These findings are compared to those from other recent North American studies, and differences are discussed. It is pointed out that accurate recurrence risk figures may not be available, and that caution should be used when counseling families with relatives who are affected with NTD.