The temporal and spatial regulation of gene expression in mammalian development is linked to the establishment of functional chromatin domains. Here, we report that tissue-specific transcription of a retrotransposon repeat in the murine growth hormone locus is required for gene activation. This repeat serves as a boundary to block the influence of repressive chromatin modifications. The repeat element is able to generate short, overlapping Pol II-and Pol III-driven transcripts, both of which are necessary and sufficient to enable a restructuring of the regulated locus into nuclear compartments. These data suggest that transcription of interspersed repetitive sequences may represent a developmental strategy for the establishment of functionally distinct domains within the mammalian genome to control gene activation.
Concentration, motility and morphology are parameters commonly used to determine the fertilization potential of an ejaculate. These parameters give a general view on the quality of sperm but do not provide information about one of the most important components of the reproductive outcome: DNA. Either single or double DNA strand breaks can set the difference between fertile and infertile males. Sperm DNA fragmentation can be caused by intrinsic factors like abortive apoptosis, deficiencies in recombination, protamine imbalances or oxidative stress. Damage can also occur due to extrinsic factors such as storage temperatures, extenders, handling conditions, time after ejaculation, infections and reaction to medicines or post-testicular oxidative stress, among others. Two singular characteristics differentiate sperm from somatic cells: Protamination and absence of DNA repair. DNA repair in sperm is terminated as transcription and translation stops post-spermiogenesis, so these cells have no mechanism to repair the damage occurred during their transit through the epididymis and post-ejaculation. Oocytes and early embryos have been shown to repair sperm DNA damage, so the effect of sperm DNA fragmentation depends on the combined effects of sperm chromatin damage and the capacity of the oocyte to repair it. In this contribution we review some of these issues.
Fatty acid synthase (FASN) is a multifunctional protein that carries out the synthesis of fatty acids so it plays a central role in de novo lipogenesis in mammals. Previously, we defined the genetic structure and expression of the bovine FASN gene. Our mapping studies placed FASN on BTA19 (19q22) where several quantitative trait loci (QTL) affecting milk-fat content and related traits have been described. This study was conducted to identify polymorphisms in the bovine FASN gene and to study their association with milk-fat content. The bovine FASN gene was screened for polymorphisms in two cattle breeds. Sequence analysis revealed several single nucleotide polymorphisms (SNPs), and two of them were analysed: a G>C substitution in the untranslated exon 1 (g.763G>C), altering a potential Sp1 transcription factor-binding site, and an A>G substitution in exon 34 (g.16009A>G), which determines a non-conservative substitution of threonine by alanine. Allele-specific amplification of the SNPs in FASN revealed significant frequency differences for both polymorphisms in Holsteins with high and low breeding values for milk-fat content. The intragenic haplotypes comprising exon 1 (alleles G and C) and exon 34 (alleles A and G) polymorphisms were studied, and the existence of linkage disequilibrium between these SNPs was found (D(CG) = 0.048, P < 0.001). Our results suggest that the FASN gene polymorphisms contribute to variation in milk-fat content. We propose that the bovine FASN gene is a candidate gene for a milk-fat content QTL.
The fundamental underlying paradigm of sexual reproduction is the production of male and female gametes of sufficient genetic difference and quality that, following syngamy, they result in embryos with genomic potential to allow for future adaptive change and the ability to respond to selective pressure. The fusion of dissimilar gametes resulting in the formation of a normal and viable embryo is known as anisogamy, and is concomitant with precise structural, physiological, and molecular control of gamete function for species survival. However, along the reproductive life cycle of all organisms, both male and female gametes can be exposed to an array of “stressors” that may adversely affect the composition and biological integrity of their proteins, lipids and nucleic acids, that may consequently compromise their capacity to produce normal embryos. The aim of this review is to highlight gamete genome organization, differences in the chronology of gamete production between the male and female, the inherent DNA protective mechanisms in these reproductive cells, the aetiology of DNA damage in germ cells, and the remarkable DNA repair mechanisms, pre- and post-syngamy, that function to maintain genome integrity.
Mesenchymal stem cells (MSCs) have a great potential for treating equine musculoskeletal injuries. Although their mechanisms of action are not completely known, their immunomodulatory properties appear to be key in their functions. The expression of immunoregulatory molecules by MSCs is regulated by proinflammatory cytokines; so inflammatory priming of MSCs might improve their therapeutic potential. However, inflammatory environment could also increase MSC immunogenicity and decrease MSC viability and differentiation capacity. The aim of this study was to assess the effect of cytokine priming on equine bone marrow-derived MSC (eBM-MSC) immunoregulation, immunogenicity, viability, and differentiation potential, to enhance MSC immunoregulatory properties, without impairing their immune-evasive status, viability, and plasticity. Equine BM-MSCs (n = 4) were exposed to 5 ng/mL of TNFα and IFNγ for 12 h (CK5-priming). Subsequently, expression of genes coding for immunomodulatory, immunogenic, and apoptosis-related molecules was analyzed by real-time quantitative polymerase chain reaction. Chromatin integrity and proliferation assays were assessed to evaluate cell viability. Trilineage differentiation was evaluated by specific staining and gene expression. Cells were reseeded in a basal medium for additional 7 days post-CK5 to elucidate if priming-induced changes were maintained along the time. CK5-priming led to an upregulation of immunoregulatory genes IDO, iNOS, IL-6, COX-2, and VCAM-1. MHC-II and CD40 were also upregulated, but no change in other costimulatory molecules was observed. These changes were not maintained 7 days after CK5-priming. Viability and differentiation potential were maintained after CK5-priming. These findings suggest that CK5-priming of eBM-MSCs could improve their in vivo effectiveness without affecting other eBM-MSC properties.
Cyclooxygenase-2 (COX-2) is upregulated in many cancers, and the prostanoids synthesized increase proliferation, improve angiogenesis, and inhibit apoptosis in several tissues. To explore the function of COX-2 in liver, transgenic (Tg) mice were generated containing a fusion gene (LIVhCOX-2) consisting of human COX-2 cDNA under the control of the human ApoE promoter. Six lines were developed; all of them expressed the LIVhCOX-2 transgene selectively in hepatocytes. The Tg mice exhibited a normal phenotype, and the increased levels of PGE 2 found were due to the constitutively expressed COX-2. Histological analysis of different tissues and macroscopic examination of the liver showed no differences between wild-type (Wt) and Tg animals.
C aveolae were originally identified with an electron microscope as flask-shaped membrane invaginations on the surface of epithelial 1 and endothelial cells. 2 These plasmalemmal vesicles are enriched in sphingolipids, cholesterol, and caveolin (Cav), the major protein constituent of these structures. 3 Three Cavs have been identified in differentiated cells with specific patterns of distribution. Cav-1 and Cav-2 are found in adipocytes and endothelial cells, 4 whereas Cav-3 is selectively expressed in muscle cells. 5 Caveolae participate in many cellular processes, including vesicular transport, 6 cholesterol homeostasis, 7 regulation of signal transduction, 8 integrin signaling, 9 and cell growth. 10 Despite this, it is rather surprising that all Cav-null mice are viable, including the complete caveola-less mouse; however, the combined loss of Cav-1 and Cav-3 has profound effects on the cardiovascular function. 11 Caveolae have now been demonstrated to concentrate a wide variety of signaling molecules, including Src family tyrosine kinases, H-Ras, heterotrimeric G protein ␣ subunits, protein kinase C isoforms, and endothelial nitric oxide synthase (NOS; i.e., NOS-3). 12 Many signaling molecules directly interact with Cav-1 through a defined modular protein domain, which is known as the Cavscaffolding domain. The Cav-scaffolding domain has been shown to directly inhibit the activation of NOS-3, 13 epidermal growth factor receptor, 14 and c-neu 15 among other molecules. Moreover, Cav-1 is a potent inhibitor of proliferative pathways such as the Ras-p42/p44 MAP (mitogen activated protein kinase) kinase cascades. 16 Cav-1 expression negatively regulates cell cycle progression through a p53/p21-dependent pathway, 17 and several cellular oncoproteins down-regulate Cav-1 expression. 10
Fatty acid synthesis differs considerably between monogastric and ruminant species. Fatty acid synthase (FASN) plays a central role in de novo lipogenesis in mammals. FASN has seven active sites which help to catalyse all the reaction steps in the conversion of acetyl-CoA and malonyl-CoA to palmitate. In this work, the bovine fatty acid synthase gene (FASN) was cloned, characterized and compared to the human and rat orthologs. Comparative analysis reveals evolutionarily conserved exon regions and gene flanking sequences. Analysis of the DNA sequence in the 5′ flanking region of the FASN bovine gene revealed a potential TATA box, CAAT box and 5 Sp1 binding sites located in a CpG island. RT-PCR and Western blot analysis showed that FASN expression was higher in brain, testis and adipose tissue than in liver and heart. The longer form of the FASN cDNA includes a 7,542-bp sequence which encodes a protein with 2,513 amino acids. An alternative transcript was discovered in bovine and ovine tissues devoid of part of exon 9. The removal of part of exon 9 by post-transcriptional splicing causes a frameshift in the open reading frame and results in a premature termination codon. We hypothesize that in ruminants, FASN may be regulated by the ratio between the two transcripts. The small transcript is mostly produced in tissues with low fatty acid synthesis.
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