Morphometric analysis of the placenta in the New World mouse Necromys lasiurus (Rodentia, Cricetidae): a comparison of placental development in cricetids and murids.

BACKGROUND: Stereology is an established method to extrapolate three-dimensional quantities from two-dimensional images. It was applied to placentation in the mouse, but not yet for other rodents. Herein, we provide the first study on quantitative placental development in a sigmodontine rodent species with relatively similar gestational time. Placental structure was also compared to the mouse, in order to evaluate similarities and differences in developmental patterns at the end of gestation. METHODS: Fetal and placental tissues of Necromys lasiurus were collected and weighed at 3 different stages of gestation (early, mid and late gestation) for placental stereology. The total and relative volumes of placenta and of its main layers were investigated. Volume fractions of labyrinth components were quantified by the One Stop method in 31 placentae collected from different individuals, using the Mercator software. Data generated at the end of gestation from N. lasiurus placentae were compared to those of Mus musculus domesticus obtained at the same stage. RESULTS: A significant increase in the total absolute volumes of the placenta and its main layers occurred from early to mid-gestation, followed by a reduction near term, with the labyrinth layer becoming the most prominent area. Moreover, at the end of gestation, the total volume of the mouse placenta was significantly increased compared to that of N. lasiurus although the proportions of the labyrinth layer and junctional zones were similar. Analysis of the volume fractions of the components in the labyrinth indicated a significant increase in fetal vessels and sinusoidal giant cells, a decrease in labyrinthine trophoblast whereas the proportion of maternal blood space remained stable in the course of gestation. On the other hand, in the mouse, volume fractions of fetal vessels and sinusoidal giant cells decreased whereas the volume fraction of labyrinthine trophoblast increased compared to N. lasiurus placenta. CONCLUSIONS: Placental development differed between N. lasiurus and M. musculus domesticus. In particular, the low placental efficiency in N. lasiurus seemed to induce morphological optimization of fetomaternal exchanges. In conclusion, despite similar structural aspects of placentation in these species, the quantitative dynamics showed important differences.

The spiny mouse (Acomys cahirinus) completes nephrogenesis before birth.

The spiny mouse is relatively mature at birth. We hypothesized that like other organs, the kidney may be more developed in the spiny mouse at birth, than in other rodents. If nephrogenesis is complete before birth, the spiny mouse may provide an excellent model with which to study the effects of an altered intrauterine environment on renal development. Due to its desert adaptation, the spiny mouse may have a reduced cortex-to-medulla ratio but an equivalent total nephron number to the C57/BL mouse. Kidneys were collected from fetal and neonatal spiny mice and sectioned for gross examination of metanephric development. Kidneys were collected from adult spiny mice (10 wk of age), and glomerular number, volume, and cortex-to-medulla ratios were determined using unbiased stereology. Nephrogenesis is complete in spiny mouse kidneys before birth. Metanephrogenesis begins at approximately day 18, and by day 38 of a 40-day gestation, the nephrogenic zone is no longer present. Spiny mice have a significantly (P < 0.001) lower total nephron number compared with C57/BL mice, although the total glomerular volume is similar. The cortex-to-medulla ratio of the spiny mouse is significantly (P < 0.01) smaller. The spiny mouse is the first rodent species shown to complete nephrogenesis before birth. This makes it an attractive candidate for the study of fetal and neonatal kidney development and function. The reduced total nephron number and cortex-to-medulla ratio in the spiny mouse may contribute to its ability to highly concentrate its urine under stressful conditions (i.e., dehydration).

Peg3 imprinted gene on proximal chromosome 7 encodes for a zinc finger protein.

Genetic and embryological studies in the mouse demonstrated functional differences between parental chromosomes during development. This is due to imprinted genes whose expression is dependent on their parental origin. In a recent systematic screen for imprinted genes, we detected Peg3 (paternally expressed gene 3). Peg3 is not expressed in parthenogenones. In interspecific hybrids, only the paternal copy of the gene is expressed in the embryos, individual tissues examined in d9.5-13.5 embryos, neonates and adults. Peg3 mRNA is a 9 kb transcript encoding an unusual zinc finger protein with eleven widely spaced C2H2 type motifs and two groups of amino acid repeats. Peg3 is expressed in early somites, branchial arches and other mesodermal tissues, as well as in the hypothalamus. Peg3 maps to the proximal region of chromosome 7. Consistent with our findings, maternal duplication of the proximal chromosome 7 causes neonatal lethality. This region is syntenic with human chromosome 19q13.1-13.3 (refs 10,11), where the genes for myotonic dystrophy and a putative tumour suppressor gene are located.

A new major histocompatibility complex class I b gene expressed in the mouse blastocyst and placenta.

Because of the role major histocompatibility complex (MHC) class I b molecules may play during mouse embryonic development, we thought it would be interesting to search for additional MHC class I b molecules that might be expressed in preimplantation embryos, and in particular in the trophoblastic lineage. We therefore screened a mouse preimplantation blastocyst cDNA library for MHC class I sequences. This search led to the identification and characterization of a new MHC class I b gene, blastocyst MHC. Sequences identical to the exons and 3' untranslated region of this gene have been found in many laboratory mouse strains, as well as in the related mouse species Mus spreciligus. The presence of this gene in mouse strains of different MHC class I haplotypes argues that blastocyst MHC is a unique, newly-described gene rather than a new allele of a previously described mouse MHC class I gene. Blastocyst MHC has the structure of an MHC class I b gene, with the six exons characteristic of T-region genes. It is linked to H2-D. The amino acid sequence encoded by this gene maintains all the features of a functional antigen-presentation domain. The blastocyst MHC gene, like the human class I b gene HLA-G, is expressed at the blastocyst stage and in the placenta, and may be the mouse analog for HLA-G.

Behavioral response of altricial and precocial rodent fetuses to acute umbilical cord compression.

Norway rat fetuses (Rattus norvegicus) exhibit a stereotypic behavioral response when the umbilical cord is experimentally compressed with a vascular clamp. In this study, the development of the fetal behavioral response to cord compression was compared in altricial and precocial rodents, which differ markedly in neural and motor maturity at the time of birth. Both altricial and precocial species showed some form of behavioral response to umbilical cord compression. Fetuses of two altricial species, Norway rats and Mongolian gerbils (Meriones unguiculatus), expressed hyperactivity in response to cord compression throughout the last third of gestation. In contrast, precocial cotton rats (Sigmodon hispidus) and spiny mice (Acomys cahirinus) did not respond to cord compression until relatively late in gestation. Thus, altricial and precocial species do not express the cord compression response during comparable periods of neural development: precocial species are much more mature at the earliest expression of this behavior than altricial species. These findings are consistent with the interpretation that the cord compression response is a behavioral adaptation that can promote survival of the fetus in utero.

Prenatal neurogenesis in the telencephalon of the precocial mouse Acomys cahirinus.

[3H]thymidine autoradiography was employed to examine the times of formation of the major neuronal classes in the forebrain of the precocial mouse Acomys cahirinus. Dams received 3 thymidine injections over a 24 h period on either embryonic Day 14, 18, 20, 22, 29 or 36. Age-related changes in the distribution and number of heavily labeled cells were noted. Acomys exhibited later onset and more protracted periods of cell generation than the phylogenetically related, altricial laboratory rat or mouse, indicating considerable differences in patterns of early growth between the species. Understanding the factors responsible for these differences could lend important insights into evolutionary mechanisms involved in the process of speciation.

[Comparative study of the brain of developed and underdeveloped neonatal rodents of the Muridae family]. / Sravnitel'noe issledovanie mozga u zrelo- i nezrelorozhdaiushchikhsia gryzunov iz semeistva myshinykh.

Morphological studies have been made of the neocortical and archicortical structures in the spiny mouse Acomys cahirinus, the only maturely born species from the family Muridae. The data obtained reveal highly developed hippocampus as compared to the neocortex in this mouse, in contrast to relationships found in other mice and rats.

Perinatal development of the small intestine and pancreas in rat and spiny mouse. Its relation to altricial and precocial timing of birth.

Rat (Rattus norvegicus) and spiny mouse (Acomys cahirinus) are closely related species that mainly differ in the developmental timing of birth. A comparison between the developmental profiles of some characteristic enzymes of the small intestine (lactase and sucrase) and of the pancreas (amylase) of both species was carried out to elucidate the question to what extent these enzymic profiles and hence the maturation of these organs was related to the process of birth. It was found that these organ-specific enzymes become first detectable at the same developmental stage in both species. Likewise, the weaning phase of the enzymic profiles occurred at the same developmental time point in both species. It is argued that both the first appearance and the weaning increase in enzyme activity follow an inherent biological program that can only be modulated by hormones. In contrast, the perinatal phase of the enzymic profile is completely dependent on the developmental timing of birth, and therefore appears not to be anchored to a particular developmental time point but rather to be dependent on birth-associated (hormonal) adaptation. In accordance with this hypothesis it was found that the development of the microscopic anatomy of the small intestine proceeded independently of the functional adaptation of the intestine to the process of birth.

Perinatal development of the lung in rat and spiny mouse: its relation to altricial and precocial timing of birth.

Rat and spiny mouse (Acomys cahirinus) are closely related murinoid species that represent altricial (rat) and precocial (spiny mouse) modes of development. The late intrauterine developmental stages of the spiny mouse therefore seem comparable to the early extrauterine developmental stages of the rat. To elucidate the question to what extent the development of the lung is related to the developmental timing of birth, we have studied some enzymes involved in the de novo synthesis of phosphatidylcholine. Of the enzymes studied, cholinephosphate cytidylyltransferase shows peaks in activity in the perinatal period (rat and spiny mouse) and at the beginning of the 3rd postnatal week (rat only). This enzyme fulfills the requirements for a developmental parameter best as changes in activity of this enzyme can be correlated with phases of cell proliferation and surface expansion in the lung of the rat. The single peak of cholinephosphate cytidylyltransferase activity in the spiny mouse as well as microscopical examination of the lung support the hypothesis that the processes of proliferation and surface expansion, which occur consecutively in the rat, develop concurrently in the spiny mouse.

Phenotypic expression in the developing murine enteric nervous system.

The development of the enteric nervous system was examined in fetal mice. Synthesis of [3H] acetylcholine ([3H]ACh) from [3H]choline and acetylcholinesterase histochemistry were used as phenotypic markers for cholinergic neurons, while the radioautographic detection of the specific uptake of [3H]serotonin (5-[3H]HT) and immunocytochemical staining with antiserum to 5-HT marked serotonergic neurons. The gut also was examined by light and electron microscopy. Development of the gut was studied in situ and in explants grown in organotypic tissue culture. Neurons were first detected morphologically in the foregut on embryonic day 12 (E12). Synthesis of [3H]ACh was detectable on days E10 to E12 but increased markedly between days E13 and E14. Uptake and radioautographic labeling by 5-[3H]HT was seen first in the foregut on day E12, in the colon on day E13, and in the terminal colon on day E14. Gut explanted from both distal and proximal bowel prior to the time when neurons could be detected (days E9 to E11) nevertheless formed neurons in culture. These cultures of early explants displayed markers for both cholinergic and serotonergic neurons. Enhances development of both cholinergic and serotonergic neurons was found in cultures explanted at day E11 over that found in cultures explanted on days E9 or E10. The evidence presented indicates (1) that enteric neurons develop from nonrecognizable precursors, (2) that the proximodistal gradient in neuronal phenotypic expression probably is not related to a proximodistal migration of precursor cells down the gut, (3) that the colonization of the bowel by neuronal precursors may be a prolonged process continuing from day E9 at least through day E11, (4) that the first pool of neuronal primordia to colonize the developing bowel can produce both cholinergic and serotonergic neurons. It is proposed that a sequential interaction of a long retained pool of dividing precursor cells with a fetal enteric microenvironment that changes as a function of time during ontogeny may be involved in producing the phenotypic diversity that characterized the enteric nervous system.