Pregnancy-Induced Physiologic Adaptation of the Abdominal Aorta Is Associated with Changes in Gene Expression and Genomic Methylation.

BACKGROUND/AIMS: Ten-eleven translocation 2 (Tet2), a DNA demethylase enzyme, has been identified as a master epigenetic regulator of vascular smooth muscle cell plasticity. We hypothesized that pregnancy will induce significant adaptive changes in aortic biomechanics that correlate with the Tet family gene expression. METHODS: Abdominal aortas from pregnant and nonpregnant mice were dissected and cannulated. Intraluminal pressure was adjusted using a pressure-servo system while using a video dimension analyzer to measure the lumen diameter. Quantitative polymerase chain reaction and immunoblot was used to analyze the expression of Tet genes. Global genomic methylation was assessed with the luminometric methylation assay. RESULTS: Compared to the nonpregnant (NP, 706 ± 8 µm) control group, the aortic luminal diameter was significantly increased in both E18.5 (836 ± 14 µm) and PP30 (889 ± 16 µm) mice. Distensibility was reduced in E18.5 (90 ± 4%) mice and returned to NP values (108 ± 2%) in PP30 (108 ± 3%) mice. Tet2 transcription decreased at the beginning of pregnancy and subsequently increased in late gestation, inversely corresponding to changes in global methylation. CONCLUSION: Physiologic changes in the aorta were accompanied by changes in gene expression and genomic methylation, suggesting an epigenetic component to maternal vascular remodeling during pregnancy.

S-layer production by Lactobacillus acidophilus IBB 801 under environmental stress conditions.

The ability of microorganisms to synthesize S-layer, the outermost structure of the microbial cell envelope composed of non-covalently bound proteins, has been ascribed to help microorganisms to exert their probiotic properties in the host. In this work, formation of S-layer by the potentially probiotic strain Lactobacillus acidophilus IBB 801 under different stress culture conditions (high incubation temperatures, presence of bile salts or NaCl, and acidic pH) was assayed. A marked S-layer synthesis by L. acidophilus IBB 801 was detected when the strain was grown at 42 °C and in the presence of 0.05 % bile salts or 2.0 % NaCl. The presence of S-layer proteins was further confirmed by transmission electron microscopy and protein identification by MS/MS. The differential expression of the proteome of this strain at 42 °C, when a marked formation of S-layer was detected, revealed the overexpression of six proteins mainly related to general stress and protein biosynthesis and translation, while four proteins detected in lower amounts were involved in DNA repair and energy metabolism. As L. acidophilus IBB 801 produces both a bacteriocin and S-layer proteins, the strain could be of interest to be used in the formulation of functional food products with specific properties.

Characterization of the mature cell surface proteinase of Lactobacillus delbrueckii subsp. lactis CRL 581.

The cell envelope-associated proteinase (CEP) of Lactobacillus delbrueckii subsp. lactis CRL 581 (PrtL) has an essential role in bacterial growth, contributes to the flavor and texture development of fermented products, and can release bioactive health-beneficial peptides during milk fermentation. The genome of L. delbrueckii subsp. lactis CRL 581 possesses only one gene that encodes PrtL, which consists of 1924 amino acids and is a multidomain protein anchored to the cell via its W domain. PrtL was extracted from the cell under high ionic strength conditions using NaCl, suggesting an electrostatic interaction between the proteinase and the cell envelope. The released PrtL was purified and biochemically characterized; its activity was maximal at temperatures between 37 and 40 °C and at pH between 7 and 8. Under optimal conditions, PrtL exhibited higher affinity for succinyl-alanyl-alanyl-prolyl-phenylalanine-p-nitroanilide than for succinyl-alanyl-glutamyl-prolyl-phenylalanine-p-nitroanilide, while methoxy-succinyl-arginyl-prolyl-tyrosyl-p-nitroanilide was not degraded. A similar α- and ß-casein degradation pattern was observed with the purified and the cell envelope-bound proteinase. Finally, on the basis of its specificity towards caseins and the unique combination of amino acids at residues thought to be involved in substrate specificity, PrtL can be classified as a representative of a new group of CEP.

Generalized disturbance of DNA methylation in the uterine decidua in the CBA/J x DBA/2 mouse model of pregnancy failure.

Nonchromosomal pregnancy failure is a common but poorly understood phenomenon. Because recent data have suggested that epigenetic abnormalities such as abnormal placental DNA methylation may play a role in human pregnancy failure, we undertook experiments to test whether decidual and/or placental DNA methylation abnormalities are present in a mouse model of pregnancy failure. A large number of studies have shown that crosses between CBA/J female mice and DBA/2 males result in pregnancies with a high rate of failure/resorption, whereas other crosses with CBA/J females produce normal pregnancies. Although the CBA/J × DBA/2 mouse has frequently been used as a model for miscarriage, a detailed explanation for the pregnancy failure phenotype is lacking. We performed timed matings between CBA/J female and DBA/2 male mice as well as between DBA/2 female and CBA/J male mice. Decidual caps were isolated at Embryonic Day (E) 9.5 from both crosses, and a microarray-based method was used to comparatively assess genomic methylation at approximately 16,000 loci on mouse chromosome 7. In comparison with decidual caps from DBA/2 × CBA/J pregnancies, CBA/J × DBA/2 decidual caps were characterized by widely and apparently randomly disturbed methylation. In another set of analogous experiments, genomic methylation of placental DNA from E8.5 pregnancies was assessed using the same microarray-based method. This analysis revealed that in contrast to the decidua, placental DNA methylation from CBA/J × DBA/2 pregnancies was indistinguishable from that of normal controls. We conclude that abnormal DNA methylation in the uterine decidua likely plays a role in the CBA/J × DBA/2 model of pregnancy failure. To our knowledge, these experiments are the first to demonstrate that epigenetic abnormalities of the decidua are associated with pregnancy failure, and they set the stage for future efforts to understand the role of DNA methylation at the maternal-fetal interface.

Recurrent pregnancy loss in a woman with NLRP7 mutation: not all molar pregnancies can be easily classified as either "partial" or "complete" hydatidiform moles.

Recurrent hydatidiform moles is an uncommon occurrence. Over the past decade, genetic studies of women with multiple recurrent molar pregnancies have revealed that maternal mutations in two different genes, NLRP7 and C6orf221, result in recurrent moles. We report a 23 year old woman, born of unrelated parents, who has experienced three molar pregnancies in succession. Whilst the first pregnancy was classified as a complete hydatidiform mole, the second and third moles defied classification as complete or partial mole using conventional histology, p57 nuclear staining pattern and ploidy studies. Molecular and cytogenetic studies proved that all three molar pregnancies were diploid and biparental in origin. Gene sequencing analysis showed that the patient is homozygous for a previously described mutation in NLRP7. A SNP microarray ruled out the presence of deletion of the NLRP7 locus. This case draws attention to the fact that recurrent molar pregnancies may be the result of specific, identifiable gene mutations, even in patients from non-consanguineous backgrounds. When pathologists encounter patients with molar pregnancies that are diploid and p57 negative and yet have fetal elements such as nucleated red blood cells or immature fetal tissues, it should heighten their suspicion of a possible genetic basis and appropriate molecular genetic workup performed with counseling offered.

Microarray assessment of methylation in individual mouse blastocyst stage embryos shows that in vitro culture may have widespread genomic effects.

BACKGROUND: Although assisted reproductive technology (ART) is reported to result in abnormal genomic imprinting and/or altered genomic methylation, few if any studies have used high-throughput methods to analyze genomic methylation in ART embryos. We hypothesized that a microarray-based assessment of genomic methylation could be used to reveal differences between ART and normal preimplantation embryos. METHODS: In this pilot study, we performed methylation-sensitive amplification of genomic DNA from preimplantation mouse blastocysts, obtained by natural mating and either maintained in vivo until E3.5 (n = 4) or cultured in vitro (n = 4) from E0.5 until E3.5. An oligonucleotide microarray was then used to perform comparative hybridization of amplified DNA, allowing us to assess relative methylation at ~16,000 loci on mouse chromosome 7. RESULTS: We show that for in vivo derived embryos, the methylation/microarray results were strikingly consistent. In contrast, all four in vitro cultured embryos showed evidence of generalized hypermethylation as well as greater locus-to-locus variability, when compared with in vivo derived embryos. Genomic segments that overlapped exons and CpG islands were most likely to be hypomethylated in both normal and experimental blastocysts. Other sequence features, such as repetitive elements, were not associated with the presence of or the degree of methylation. CONCLUSIONS: We conclude that a general assessment of genomic methylation in blastocyst stage embryos is technically feasible. Data from this small sample suggest that in vitro embryo culture is associated with generalized hypermethylation as well as increased locus-to-locus variability in methylation. However, it is premature to conclude that this is a general property of in vitro cultured blastocysts.

Aneuploidy detection in mixed DNA samples by methylation-sensitive amplification and microarray analysis.

BACKGROUND: Cell-free fetal nucleic acid, believed to be derived from the placenta/trophoblast, is present in the plasma of pregnant women; however, its use for predictive genetic testing has been severely limited because the circulating fetal DNA is present in a small quantity and mixed with a much larger quantity of maternal DNA. Methods for detecting fetal aneuploidy from the cell-free fetal DNA in plasma are highly sought after, but proposed methods must take into account the small quantity and highly contaminated nature of the available fetal DNA. METHODS: We developed a method for methylation-sensitive amplification of DNA suitable for use with small (approximately 1 ng) samples. We used this method in conjunction with 2-color microarray analysis with a custom-made array to investigate whether relative amplification, and hence relative methylation, could be evaluated for a large number of genomic loci. RESULTS: Microarray assessment of genomic methylation accurately predicted the degree of methylation measured with bisulfite-conversion PCR and confirmed that DNA from first-trimester trophoblast was generally hypomethylated compared with whole-blood DNA. With a series of 3 samples in which 1 ng of DNA from a trisomic first trimester placenta was mixed with 9 ng of chromosomally normal peripheral blood DNA, we observed that the microarray signal associated with the trisomic chromosome was significantly different from that of the other chromosomes (P < 0.001). CONCLUSIONS: This method has potential to be used for noninvasive detection of fetal aneuploidy.

Zic2 is expressed in pluripotent cells in the blastocyst and adult brain expression overlaps with makers of neurogenesis.

Members of the zic family of transcription factors are widely understood to act during neural patterning and neural crest development. In particular, studies in mice and humans have shown that Zic2 has a role in forebrain patterning, while studies in Xenopus and zebrafish have shown that Zic2 acts during gastrulation. Expression of Zic2 prior to gastrulation has not been reported in the mouse. In the adult, Zic2 is known to be strongly expressed in cerebellar granule cells, but expression elsewhere in the adult brain has not been reported. We present data showing that Zic2 is expressed in pluripotent cells during very early mouse development. Further, in the adult brain, Zic2 expression is broad and overlaps with markers of neurogenesis. The presence of Zic2 in pluripotent cells of the embryo as well as in dividing neural cells in the adult suggests that this transcription factor may have a role in maintaining pluripotency.

Alanine tracts: the expanding story of human illness and trinucleotide repeats.

Expansions of polyglutamine repeats are known to cause a variety of human neurodegenerative diseases. More recently, expansions of alanine tracts, particularly in transcription factor genes, have been shown to cause at least nine human conditions, including mental retardation and malformations of the brain, digits and other structures. Present knowledge suggests that alanine tract expansions generally, but not always, arise through unequal recombination as opposed to replication slippage, the most likely mechanism in other triplet repeat expansions. The function of alanine tracts is unknown but when alanine expansions occur in transcription factor genes, alanine tracts can result in either loss-of-function or gain of an abnormal function. Given the frequency of alanine tracts in proteins, it is likely that more alanine tract expansions will be discovered in disease genes.

YebC, a putative transcriptional factor involved in the regulation of the proteolytic system of Lactobacillus.

The proteolytic system of Lactobacillus plays an essential role in bacterial growth, contributes to the flavor development of fermented products, and can release bioactive health-beneficial peptides during milk fermentation. In this work, a genomic analysis of all genes involved in the proteolytic system of L. delbrueckii subsp. lactis CRL 581 was performed. Genes encoding the cell envelope-associated proteinase, two peptide transport systems, and sixteen peptidases were identified. The influence of the peptide supply on the transcription of 23 genes involved in the proteolytic system of L. delbrueckii subsp. lactis was examined after cell growth in a chemically defined medium (CDM) and CDM supplemented with Casitone. prtL, oppA 1, optS, optA genes as well as oppDFBC and optBCDF operons were the most highly expressed genes in CDM; their expression being repressed 6- to 115-fold by the addition of peptides. The transcriptional analysis was confirmed by proteomics; the up-regulation of the PrtL, PepG, OppD and OptF proteins in the absence of peptides was observed while the DNA-binding protein YebC was up-regulated by peptides. Binding of YebC to the promoter region of prtL, oppA 1, and optS, demonstrated by electrophoretic mobility shift assays, showed that YebC acts as a transcriptional repressor of key proteolytic genes.

Lactic Acid Bacteria as Cell Factories for the Generation of Bioactive Peptides.

There is a growing interest in the incorporation of functional foods in the daily diet to achieve health promotion and disease risk reduction. Numerous studies have focused on the production of biologically active peptides as nutraceuticals and functional food ingredients due to their health benefits. These short peptides, displaying antihypertensive, antioxidant, mineral binding, immunomodulatory and antimicrobial activities are hidden in a latent state within the primary sequences of food proteins requiring enzymatic proteolysis for their release. While microbial fermentation is one of the major and economically most convenient processes used to generate bioactive peptides, lactic acid bacteria (LAB) are widely used as starter cultures for the production of diverse fermented foods. This article reviews the current knowledge on LAB as cell factories for the production of bioactive peptides from a variety of food protein sources. These microorganisms depend on a complex proteolytic system to ensure successful fermentation processes. In the dairy industry, LAB containing cell envelope-associated proteinases (CEPs) are employed as biocatalysts for the first step of casein breakdown releasing bioactive peptides during milk fermentation. A better understanding of the functionality and regulation of the proteolytic system of LAB opens up future opportunities for the production of novel food-derived compounds with potential health-promoting properties.

Immunolocalization of Zic2 expression in the developing mouse forebrain.

The Zic genes are a family of zinc finger transcription factors defined by their homology with the Drosophila gene, odd-paired (opa). Zic2 has a critical role in forebrain development, as is evidenced by the fact that, in both mice and humans, diminished expression results in the severe forebrain malformation known as holoprosencephaly. Published information indicates that Zic2 expression is most prominent in the dorsal neural tube/spinal cord and in the hindbrain; however, there is no published description of the pattern of expression of Zic2 in the developing forebrain where the main Zic2 associated phenotype occurs. Using a Zic2-specific antiserum, we present new information about the expression of Zic2 in the developing mouse forebrain. In addition, we show that in sonic hedgehog (Shh) null mice, the expression of Zic2 is expanded ventrally in some structures while absent in others, suggesting that Shh has a role in regulating the expression of Zic2.

Possible association of NTDs with a polyhistidine tract polymorphism in the ZIC2 gene.

Neural tube defects (NTDs) and brain malformations represent a common finding in chromosome 13q deletion patients. Hemizygosity for ZIC2, which is located in the 13q32 critical deletion region, results in holoprosencephaly (HPE) in humans, and diminished expression of ZIC2 results in HPE as well as lumbosacral NTDs in mice. Taken together, these observations led us to hypothesize that ZIC2 mutations may be a cause of isolated NTD. To test this, we screened 192 NTD patients for mutations in ZIC2. While we did not find ZIC2 mutations in these patients, we did find some evidence of a possible association between a histidine tract polymorphism in ZIC2 and NTDs. Our sample was too small to reach definitive conclusions, but the evidence is sufficiently intriguing to encourage further research. If this association is confirmed, subtle alterations in ZIC2 activity may confer a risk of NTD.

Genome Sequence of the Cheese-Starter Strain Lactobacillus delbrueckii subsp. lactis CRL 581.

We report the genome sequence of Lactobacillus delbrueckii subsp. lactis CRL 581 (1,911,137 bp, GC 49.7%), a proteolytic strain isolated from a homemade Argentinian hard cheese which has a key role in bacterial nutrition and releases bioactive health-beneficial peptides from milk proteins.

Molecular regulation of the developing commissural plate.

Coordinated transfer of information between the brain hemispheres is essential for function and occurs via three axonal commissures in the telencephalon: the corpus callosum (CC), hippocampal commissure (HC), and anterior commissure (AC). Commissural malformations occur in over 50 human congenital syndromes causing mild to severe cognitive impairment. Disruption of multiple commissures in some syndromes suggests that common mechanisms may underpin their development. Diffusion tensor magnetic resonance imaging revealed that forebrain commissures crossed the midline in a highly specific manner within an oblique plane of tissue, referred to as the commissural plate. This specific anatomical positioning suggests that correct patterning of the commissural plate may influence forebrain commissure formation. No analysis of the molecular specification of the commissural plate has been performed in any species; therefore, we utilized specific transcription factor markers to delineate the commissural plate and identify its various subdomains. We found that the mouse commissural plate consists of four domains and tested the hypothesis that disruption of these domains might affect commissure formation. Disruption of the dorsal domains occurred in strains with commissural defects such as Emx2 and Nfia knockout mice but commissural plate patterning was normal in other acallosal strains such as Satb2(-/-). Finally, we demonstrate an essential role for the morphogen Fgf8 in establishing the commissural plate at later developmental stages. The results demonstrate that correct patterning of the commissural plate is an important mechanism in forebrain commissure formation.

Validation of QF-PCR for prenatal aneuploidy screening in the United States.

OBJECTIVE: QF-PCR is an inexpensive and reliable method for aneuploidy screening; however, despite its obvious advantages, it is not in routine use in the United States. Our objective in the present study was to validate QF-PCR as a means for prenatal aneuploidy screening in our institution. METHODS: A QF-PCR assay using 15 primer pairs located on chromosomes 13, 18, 21 X and Y was established for aneuploidy screening. Amniotic fluid (AF) and chorionic villus sampling (CVS) samples consisting only of the cells recovered from the plasticware discarded by our institutional cytogenetics laboratory were collected and DNA was prepared by a simple and inexpensive microwave procedure. QF-PCR was then performed and interpreted using established criteria. RESULTS: 687 consecutive prenatal samples were screened in a blinded prospective manner, and results were compared to those obtained by conventional cytogenetics. 100% of autosomal trisomies were detected, and there were zero false positives. A single case each of XXY and 45X were missed. CONCLUSIONS: QF-PCR for prenatal aneuploidy screening was validated in our laboratory and has now been approved by the New York State Clinical Laboratory Evaluation Program. We propose a simple protocol for integrating QF-PCR into the normal cytogenetics laboratory workflow.

In vitro analysis of partial loss-of-function ZIC2 mutations in holoprosencephaly: alanine tract expansion modulates DNA binding and transactivation.

Heterozygous loss-of-function mutations in ZIC2 result in the severe brain malformation known as holoprosencephaly (HPE), indicating that forebrain development is exquisitely sensitive to the activity of this poorly understood transcription factor. To identify the regions of ZIC2 that are essential for activity, we have assessed the ability of a variety of ZIC2 mutant proteins to function in in vitro assays. Two sources of information were used to design relevant mutations. First, phenotype producing mutations in human and in mouse ZIC2 were mimicked and secondly, a comparative sequence analysis of the C-terminal was carried out. Analysis of these mutations suggests that either a decrease or an increase in ZIC2 mediated transcriptional activity can produce a forebrain phenotype. In addition, the analysis reveals that the C-terminal of ZIC2 contains both activation and repression domains. This region of ZIC2 contains an alanine-tract, and expansion of this domain is associated with HPE. In vitro analysis of proteins with alterations in alanine-tract length illustrates that the C-terminal alanine-tract of ZIC2 influences the strength of DNA binding and alters transcriptional activity in a promoter-specific manner. This finding provides a possible mechanism by which alanine-tract expansion mutations could alter the function of other transcription factors.

Zic2 patterns binocular vision by specifying the uncrossed retinal projection.

During CNS development, combinatorial expression of transcription factors controls neuronal subtype identity and subsequent axonal trajectory. Regulatory genes designating the routing of retinal ganglion cell (RGC) axons at the optic chiasm to the appropriate hemisphere, a pattern critical for proper binocular vision, have not been identified. Here, we show that the zinc finger transcription factor Zic2, a vertebrate homolog of the Drosophila gene odd-paired, is expressed in RGCs with an uncrossed trajectory during the period when this subpopulation grows from the ventrotemporal retina toward the optic chiasm. Loss- and gain-of-function analyses indicate that Zic2 is necessary and sufficient to regulate RGC axon repulsion by cues at the optic chiasm midline. Moreover, Zic2 expression reflects the extent of binocularity in different species, suggesting that Zic2 is an evolutionarily conserved determinant of RGCs that project ipsilaterally. These data provide evidence for transcriptional coding of axon pathfinding at the midline.