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Postnatal Expression (postnatal + expression)

Distribution by Scientific Domains
Life Sciences75%

Selected Abstracts

Expression pattern of Popdc2 during mouse embryogenesis and in the adult

DEVELOPMENTAL DYNAMICS, Issue 3 2008
Alexander Froese
Abstract The Popdc2 gene is a member of the Popeye domain containing gene family encoding membrane proteins with prominent expression in striated and smooth muscle tissue. After introducing a LacZ reporter gene into the Popdc2 locus, expression was studied during embryonic development and postnatal life. At embryonic day (E) 7.5, expression was present in cardiac and extraembryonic mesoderm. At E10.5, expression was found in heart, somites, and mesothelial cells lining the coelom. At E12.5, expression was present in the coelomic mesothelium, pericardial and myocardial layer of the heart, skeletal muscle, bladder, gut, and umbilical vessels. Postnatal expression was found in cardiac and skeletal muscle and in the smooth muscle layer of colon, rectum, and bladder. In the stomach, Popdc2 was exclusively present in the pyloric epithelium. In conclusion, Popdc2 is expressed in various muscle and nonmuscle cell types during embryonic development and in postnatal life. Developmental Dynamics 237:780,787, 2008. © 2008 Wiley-Liss, Inc. [source]

Differential expression of c- erb B2/neu, epidermal growth factor receptor, cytokeratin 8, and the prostatic steroid-binding protein gene in rat ventral prostate during postnatal development

THE PROSTATE, Issue 3 2001
Louis L. Pisters
Abstract BACKGROUND The development and progression of prostate neoplasia may recapitulate the early developmental pattern of expression of genes in the prostate. The study of prostate development may, therefore, provide insights into the molecular mechanisms important in prostate neoplasia and reveal new markers. METHODS We compared postnatal expression of four genes: neu and epidermal growth factor receptor genes (EGFR), androgen-upregulated in the ventral prostate of adult rats (C-3), and androgen-repressed (CK8) in Sprague,Dawley rats. In situ hybridization was performed on prostate frozen sections collected on postnatal days 1, 5, 10, 15, 20, 30, and 60 from five rats per day. Staining intensities for antisense probes specific for each gene were determined relative to day 1 intensity. RESULTS Growth factor receptors including neu and EGFR may be coordinately regulated in the basal-cell population during prostate development. CK8 and C-3 show evidence of similar androgen regulation during development. CONCLUSIONS CK8 and C-3 have distinct patterns of expression in the postnatal period of development and these genes may be good markers of differentiation. Both neu and EGFR may be involved in androgen-independent growth of basal cell population in prostate. Prostate 47:164,171, 2001. © 2001 Wiley-Liss, Inc. [source]

Postnatal changes in the expression of genes located in the callipyge region in sheep skeletal muscle

ANIMAL GENETICS, Issue 6 2006
A. C. Perkins
Summary The expression of five genes surrounding the callipyge (CLPG) mutation was analysed in skeletal muscles from lambs at one prenatal and two postnatal ages that coincide with the onset and establishment of muscle hypertrophy. Genotype-specific changes in transcript abundance were detected for paternal allele-specific DLK1 and PEG11 (the official symbol of the latter is RTL1) and the maternal allele-specific MEG3, PEG11AS and MEG8 when the mutation was inherited in cis. There were differences in the temporal and muscle-specific effects on expression between the maternal allele-specific genes and paternal allele-specific genes. Maternal inheritance of the CLPG allele had a significant effect on the expression of MEG3 and MEG8 at prenatal and postnatal ages, whereas paternal inheritance of DLK1 and PEG11 only affected postnatal expression. Genotype-specific changes in PEG11AS expression were detected only in prenatal muscle. Maternal inheritance of the mutation caused similar changes in MEG3 and MEG8 expression in the semimembranosus, which undergoes hypertrophy, and the supraspinatus, which does not hypertrophy. Paternal inheritance of the mutation caused changes in PEG11 expression in both muscles, although the magnitude of expression in semimembranosus was more than 100-fold greater than in supraspinatus. DLK1 expression was upregulated in callipyge animals at both postnatal ages in the semimembranosus, but there was no effect of genotype on DLK1 expression in the supraspinatus at any age. Increased DLK1 expression was likely the primary cause of muscle hypertrophy, but a contribution of PEG11 to the phenotype cannot be ruled out based on gene expression. [source]

Differential expression of the GTL2 gene within the callipyge region of ovine chromosome 18

ANIMAL GENETICS, Issue 5 2001
C. A. Bidwell
The inheritance pattern of the skeletal muscle hypertrophy phenotype caused by the callipyge gene has been characterized as polar overdominance. We hypothesized that this trait may be caused by a gain or loss of gene expression because of the reversible nature of the phenotype in paternal vs. maternal inheritance. Suppression subtraction cDNA probes were made from skeletal muscle mRNA of normal (NN) and callipyge (CPatNMat) animals and hybridized to Southern blots containing bacterial artificial chromosomes (BACs) that comprise a physical contig of the callipyge region. The CN,NN probes hybridized to two ovine and seven bovine BACs. Sequence analysis of fragments within those BACs indicated short regions of similarity to mouse gene trap locus (gtl2). Northern blots analysis of RNA from hypertrophy-responsive muscles show a population of GTL2 mRNA centred around 2.4 kb that were abundantly expressed in 14-day prenatal NN and CPatNMat lambs but were down-regulated in day 14 and day 56 postnatal NN lambs. The expression of GTL2 remained elevated in 14- and 56-day-old CPatNMat lambs as well as in 56-day-old NPatCMat and CC lambs. Expression of GTL2 in the supraspinatus, which does not undergo hypertrophy, was very low for all genotypes and ages. Isolation of cDNA sequences show extensive alternative splicing and a lack of codon bias suggesting that GTL2 does not encode a protein. The mutation of the callipyge allele has altered postnatal expression of GTL2 in muscles that undergo hypertrophy and will help identify mechanisms involved in growth, genomic imprinting and polar overdominance. [source]