The Prechordal Plate, the Rostral End of the Notochord and Nearby Median Features in Staged Human Embryos

Müller, Fabiola; OʼRahilly, Ronan

doi:10.1159/000068214

Cited by 35 publications

(25 citation statements)

References 19 publications

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“…1995). Important differences occur, for example, with regard to: (1) the prechordal plate and the notochordal process (Müller & O’Rahilly, 2003); (2) the absence of neural crest in the human forebrain, although present in the rat (Bartelmez, 1960); and (3) the different pattern of closure of the neural folds (O’Rahilly & Müller, 2002). It is also important to keep in mind that until now ‘molecular genetics has not solved the problem of head segmentation.…”

Section: Introductionmentioning

confidence: 99%

Segmentation in staged human embryos: the occipitocervical region revisited

Müller

OʼRahilly

2003

Journal of Anatomy

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The first seven somites, the rhombomeres, and the pharyngeal arches were reassessed in 145 serially sectioned human embryos of stages 9 -23, 22 of which were controlled by precise graphic reconstructions. Segmentation begins in the neuromeres, somites and aortic arches at stage 9. The following new observations are presented.(1) The first somite in the human, unlike that of the chick, is neither reduced in size nor different in structure, and it possesses sclerotome, somitocoel and dermatomyotome. (2) Somites 1-4, unlike those of the chick, are related to rhombomere 8 (rather than 7 and 8) and are caudal to pharyngeal arch 4 (rather than in line with 3 and 4). (3) Occipital segment 4 resembles a developing vertebra more than do segments 1-3. (4) The development of the basioccipital resembles that of the first two cervical vertebrae in that medial and lateral components arise in a manner that differs from that in the rest of the vertebral column. (5) The two groups of somites, occipital 1-4 and cervical 5-7, each form a median skeletal mass. (6) An 'S-shaped head/trunk interface', described for the chick and unjustifiably for the mouse, was not found because it is not compatible with the topographical development of the otic primordium and somite 1, between which neural crest migrates without hindrance in mammals. (7) Occipital segmentation and related features are documented by photomicrographs and graphic interpretations for the first time in the human. It is confirmed that the first somite, unlike that of the chick, is separated from the otic primordium by a distance, although the otic anlage undergoes a relative shift caudally. The important, although frequently neglected, distinction between lateral and medial components is emphasized. Laterally, sclerotomes 3 and 4 delineate the hypoglossal foramen, 4 gives rise to the exoccipital and participates in the occipital condyle, 5 forms the posterior arch of the atlas and 6 provides the neural arch of the axis, which is greater in height than the arches of the other cervical vertebrae. Medially, the perinotochord and migrated sclerotomic cells give rise to the basioccipital as well as to the vertebral centra, including the tripartite column of the axis. Registration between (1) the somites and (2) the occipital and cervical medial segments becomes interrupted by the special development of the axis, the three components of which come to occupy the height of only 2 1 / 2 segments.

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Section: Introductionmentioning

confidence: 99%

Segmentation in staged human embryos: the occipitocervical region revisited

Müller

OʼRahilly

2003

Journal of Anatomy

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“…Paralleling the process of neural tube closure is early head patterning and midline specification, which begins around E7.5 (73) in mice or at stage 7-10 (wk 3-4) of human development (70,74). Failure of this process leads to HPE and associated midline facial defects, such as cyclopia or proboscis.…”

Section: Figure 2 Parity Increases Defects In Twsg1mentioning

confidence: 99%

Maternal Diet Supplementation with Methyl Donors and Increased Parity Affect the Incidence of Craniofacial Defects in the Offspring of Twisted gastrulation Mutant Mice

Billington

Schmidt

Zhang

et al. 2013

The Journal of Nutrition

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Diets rich in methyl-donating compounds, including folate, can provide protection against neural tube defects, but their role in preventing craniofacial defects is less clear. Mice deficient in Twisted gastrulation (TWSG1), an extracellular modulator of bone morphogenetic protein signaling, manifest both midline facial defects and jaw defects, allowing study of the effects of methyl donors on various craniofacial defects in an experimentally tractable animal model. The goal of this study was to examine the effects of maternal dietary supplementation with methyl donors on the incidence and type of craniofacial defects among Twsg1 2/2 offspring. Nulliparous and primiparous female mice were fed an NIH31 standard diet (control) or a methyl donor supplemented (MDS) diet (folate, vitamin B-12, betaine, and choline). Observed defects in the pups were divided into those derived mostly from the first branchial arch (BA1) (micrognathia, agnathia, cleft palate) and midline facial defects in the holoprosencephaly spectrum (cyclopia, proboscis, and anterior truncation). In the first pregnancy, offspring of mice fed the MDS diet had lower incidence of BA1-derived defects (12.8% in MDS vs. 32.5% in control; P = 0.02) but similar incidence of midline facial defects (6.4% in MDS vs. 5.2% in control; P = 1.0). Increased maternal parity was independently associated with increased incidence of craniofacial defects after adjusting for diet (from 37.7 to 59.5% in control, P = 0.04 and from 19.1 to 45.3% in MDS, P = 0.045). In conclusion, methyl donor supplementation shows protective effects against jaw defects, but not midline facial defects, and increased parity can be a risk factor for some craniofacial defects.

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“…PP cells arise during gastrulation rostral to the head process (diagram Fig. 7) and exist in the human (Muller and O'Rahilly, 2002) and mouse (Poelmann, 1981) embryos.…”

Section: Pp and Ncmentioning

confidence: 99%