Jacqueline Barra

ALTERED CONTROL OF CELLULAR PROLIFERATION IN THE ABSENCE OF MAMMALIAN BRAHMA (SNF2ALPHA )

The mammalian SWI–SNF complex is an evolutionarily conserved, multi‐subunit machine, involved in chromatin remodelling during transcriptional activation. Within this complex, the BRM (SNF2α) and BRG1 (SNF2β) proteins are mutually exclusive subunits that are believed to affect nucleosomal structures using the energy of ATP hydrolysis. In order to characterize possible differences in the function of BRM and BRG1, and to gain further insights into the role of BRM‐containing SWI–SNF complexes, the mouse BRM gene was inactivated by homologous recombination. BRM−/− mice develop normally, suggesting that an observed up‐regulation of the BRG1 protein can functionally replace BRM in the SWI–SNF complexes of mutant cells. Nonetheless, adult mutant mice were ∼15% heavier than control littermates. This may be caused by increased cell proliferation, as demonstrated by a higher mitotic index detected in mutant livers. This is supported further by the observation that mutant embryonic fibroblasts were significantly deficient in their ability to arrest in the G0/G1 phase of the cell cycle in response to cell confluency or DNA damage. These studies suggest that BRM participates in the regulation of cell proliferation in adult mice.

Expression of the vHNF1/HNF1β homeoprotein gene during mouse organogenesis

Formation of tubular structures from an epithelial tissue is a process common to many morphogenetic events during organogenesis. We report here new data concerning the expression pattern of the vHNF1/HNF1beta gene during this process in the mouse. vHNF1 (variant Hepatocyte Nuclear Factor 1) is a member of the HNF1 homeoprotein family. Its expression domain includes organs such as the liver, the kidney, the lung and the pancreas, but is restricted to the epithelial cells of these organs. To follow vHNF1 expression during organogenesis, we have introduced a NLS-lacZ gene under the control of vHNF1 regulatory regions by homologous recombination. Detection of the beta-galactosidase activity in heterozygous mice demonstrates that this gene is expressed in numerous tubular epitheliums as soon as they appear and all along development.

Shifting boundaries of retinoic acid activity control hindbrain segmental gene expression

Retinoic acid (RA) generated by Raldh2 in paraxial mesoderm is required for specification of the posterior hindbrain, including restriction of Hoxb1 expression to presumptive rhombomere 4 (r4). Hoxb1 expression requires 3′ and 5′ RA response elements for widespread induction up to r4 and for r3/r5 repression, but RA has previously been detected only from r5-r8, and vHnf1 is required for repression of Hoxb1 posterior to r4 in zebrafish. We demonstrate in mouse embryos that an RA signal initially travels from the paraxial mesoderm to r3, forming a boundary next to the r2 expression domain of Cyp26a1 (which encodes an RA-degrading enzyme). After Hoxb1 induction, the RA boundary quickly shifts to r4/r5, coincident with induction of Cyp26c1 in r4. A functional role for Cyp26c1 in RA degradation was established through examination of RA-treated embryos. Analysis of Raldh2–/– and vHnf1–/– embryos supports a direct role for RA in Hoxb1 induction up to r4 and repression in r3/r5, as well as an indirect role for RA in Hoxb1 repression posterior to r4 via RA induction of vHnf1 up to the r4/r5 boundary. Our findings suggest that Raldh2 and Cyp26 generate shifting boundaries of RA activity, such that r3-r4 receives a short pulse of RA and r5-r8 receives a long pulse of RA. These two pulses of RA activity function to establish expression of Hoxb1 and vHnf1 on opposite sides of the r4/r5 boundary.

Rescue of Preimplantatory Egg Development and Embryo Implantation in Prolactin Receptor-Deficient Mice after Progesterone Administration.

PRL, a hormone secreted essentially by the pituitary and other extrapituitary sources such as decidua, has been attributed regulatory roles in reproduction and cell growth in mammals. These effects are mediated by a membrane PRL receptor belonging to the cytokine receptor superfamily. Null mutation of the PRL receptor gene leads to female sterility due to a severely compromised preimplantation development and a complete failure of the implantation of the few embryos reaching the blastocyst stage, strongly implicating PRL in the maternal control of implantation. We measured the hormonal status of -/- mice, which confirmed that the corpus luteum is unable to produce progesterone. Progesterone administration to -/- mice completely rescued the development of preimplantatory eggs and embryo implantation. Pregnancy could be maintained to 19.5 days postcoitum, with about 22% of resulting embryos reaching adulthood. Although progesterone and perhaps PRL appear to facilitate mouse preembryo development throughout the preimplantation stages, other factors as well as a possible direct effect of PRL on the uterus are probably necessary to fully maintain pregnancy. Finally, reduced ductal side-branching in the mammary gland can be rescued by progesterone treatment, but females exhibit reduced alveolar formation. Our model establishes the PRL receptor as a key regulator of reproduction and provides novel insights into the function of lactogenic hormones and their receptor.

pdsA, a gene involved in the production of active phosphodiesterase during starvation of Dictyostelium discoideum amoebae.

SummaryUpon starvation, amoebae of the mutant strain HPX235 are unable to aggregate. Previous work has shown that this aggregateless character was associated with a nearly complete block in the production of the phosphodiesterase by these cells. Aggregation of the HPX235 amoebae can be induced with exogenous phosphodiesterase. In the present work, we show that both the aggregateless character and the block in phosphodiesterase production appear to result from the same recessive mutation, allocated to I.g.IV. Two other mutant strains displaying a comparable phenotype (HPX262 and HP594) were shown by complementation to belong to the same locus pdsA. Unlike wild type cells, the mutants of the locus pdsA cannot be induced to produce phosphodiesterase following treatment of the cells with exogenous cAMP, whether exogenous phosphodiesterase is present or not in the starvation buffer. It is concluded that pdsA is either the structural gene for the phosphodiesterase or a controlling element whose integrity is required for phosphodiesterase production. Mutations in pdsA share secondary effects among which the abnormally low production of the phosphodiesterase inhibitor. However, this effect can be overcome upon addition of exogenous phosphodiesterase, and most likely results from the lack of cAMP hydrolysis.The late development is also affected in pdsA mutants. Aggregates formed in the presence of exogenous phosphodiesterase cannot culminate normally. This suggests that the level of cAMP hydrolysis also plays a role during the late stages of development of Dictyostelium discoideum.

Participation of the paternal genome is not required before the eight-cell stage for full-term development of mouse embryos

Differential expression of the paternal and maternal genomes during mouse embryonic development is considered a reason for both genomes being required for development to term. Extending previous studies performed on two-cell embryos, we show here that diploid embryos reconstituted at the four-cell stage from uniparental haploid blastomeres can produce living offspring. This result shows that for normal development to occur, a paternal genome does not need to be associated with a maternal genome within the same nucleus before the eight-cell stage.

Gene trap insertion reveals two open reading frames in the mouse SSeCKS gene: the form predominantly detected in the nervous system is suppressed by the insertion while the other, specific of the testis, remains expressed

Scaffold proteins play an important role in regulating signal transduction by targeting kinases and phosphatases in close proximity to their relevant substrates. SSeCKS protein has been described as a protein kinase C and A (PKC/PKA) anchoring protein as well as a PKC substrate with a tumor suppressor activity. In this study, we report the generation, via gene trapping in embryonic stem cells of mice carrying an insertion in the mouse SSeCKS gene. Through the molecular analysis of the insertion site, we show that SSeCKS contains two alternative promoters directing the synthesis of mRNAs (P1- and P2-mRNA), encoding two different proteins, one of which would be a truncated form of the other. Interestingly, these RNAs are differentially expressed, P2 being found exclusively in the male germ line, while P1 exhibits a dynamic and wider pattern of expression during embryonic development and in the adult; its expression is predominant in the nervous system. Finally, we show that P1- but not P2-mRNA expression is abolished by the insertion and furthermore that mice homozygous for the mutation lack SSeCKS in all tissues except the male germ cells. Nevertheless and surprisingly, these mice do not exhibit any obvious phenotype. The functional implications of these observations are discussed.

Unexpected behavior of a gene trap vector comprising a fusion between the Sh ble and the lacZ genes

A new gene trap vector has been designed, comprised of a fusion between the Sh ble gene, which confers resistance to the antibiotic phleomycin, and the lacZ gene (phleal fusion gene). A synthetic splice acceptor, made of the yeast branchpoint followed by a pyrimidin‐rich sequence of 27 nucleotides, is included at the 5′ extremity. The linearized gene trap vector was introduced into mouse embryonic stem cells (ES cells), and 40 phleomycin resistant (phleAL) cell lines possessing a single copy of the insert were selected. They were stable in expressing the lacZ gene. Reporter gene expression was studied at days 8.5 and 10.5 of embryonic development in chimeric embryos obtained after injection of phleoL ES clones into 8‐cell stage embryos. Out of 20 phleal lines examined, 14 exhibited β‐galactosidase expression at day 10.5. Use of the phleal fusion gene trap vector to select genes expressed in ES cells, therefore, is compatible with the isolation of genes expressed at midgestation. However, and most intriguingly, 10 out of these 14 cell lines (71%) displayed reporter gene expression mostly in heart and liver. Two of them exhibited, in addition, expression in central nervous system (CNS) or in CNS and limb buds, respectively. Germline chimeras were subsequently obtained and 15 mouse lines have been established. Intercrosses of animals heterozygous for the insertion revealed a mutant phenotype in several lines.

A PHOSPHODIESTERASE-DEFECTIVE MUTANT OF DICTYOSTELIUM DISCOIDEUM

Publisher Summary This chapter presents a data concerning an aggregate-less mutant of Dictyostelium discoideum, which appears defective in phosphodiesterase (PD) production. Its aggregation-deficient phenotype may be corrected upon addition to the starvation media of rat brain PD. Mutant amoebae also respond to supernatant media in which Dictyostelium discoideum amoebae were starved. The active factor present in these media is thought to be a peculiar fraction of the extracellular PD activity that is resistant to the inhibitor. Genetic analysis of the mutant strain suggests that the mutation responsible for the aggregate-less character is located on linkage group 4. The chapter also presents existence of an extracellular inhibitor-resistant PD activity.