Cdk12 is essential for embryonic development and the maintenance of genomic stability.

The maintenance of genomic integrity during early embryonic development is important in order to ensure the proper development of the embryo. Studies from cultured cells have demonstrated that cyclin-dependent kinase 12 (Cdk12) is a multifunctional protein that maintains genomic stability and the pluripotency of embryonic stem cells. Perturbation of its functions is also known to be associated with pathogenesis and drug resistance in human cancers. However, the biological significance of Cdk12 in vivo is unclear. Here we bred mice that are deficient in Cdk12 and demonstrated that Cdk12 depletion leads to embryonic lethality shortly after implantation. We also used an in vitro culture system of blastocysts to examine the molecular mechanisms associated with the embryonic lethality of Cdk12-deficient embryos. Cdk12(-/-) blastocysts fail to undergo outgrowth of the inner cell mass because of an increase in the apoptosis of these cells. Spontaneous DNA damage was revealed by an increase in 53BP1 foci among cells cultured from Cdk12(-/-) embryos. Furthermore, the expression levels of various DNA damage response genes, namely Atr, Brca1, Fanci and Fancd2, are reduced in Cdk12(-/-) embryos. These findings indicate that Cdk12 is important for the correct expression of some DNA damage response genes and indirectly has an influence on the efficiency of DNA repair. Our report also highlights that DNA breaks occurring during DNA replication are frequent in mouse embryonic cells and repair of such damage is critical to the successful development of mouse embryos.

Protogenin prevents premature apoptosis of rostral cephalic neural crest cells by activating the α5ß1-integrin.

The bones and connective tissues of the murine jaws and skull are partly derived from cephalic neural crest cells (CNCCs). Here, we report that mice deficient of protogenin (Prtg) protein, an immunoglobulin domain-containing receptor expressed in the developing nervous system, have impairments of the palatine and skull. Data from lineage tracing experiments, expression patterns of neural crest cell (NCC) marker genes and detection of apoptotic cells indicate that the malformation of bones in Prtg-deficient mice is due to increased apoptosis of rostral CNCCs (R-CNCCs). Using a yeast two-hybrid screening, we found that Prtg interacts with Radil, a protein previously shown to affect the migration and survival of NCCs in zebrafish with unknown mechanism. Overexpression of Prtg induces translocation of Radil from cytoplasm to cell membrane in cultured AD293 cells. In addition, overexpression of Prtg and Radil activates α5ß1-integrins to high-affinity conformational forms, which is further enhanced by the addition of Prtg ligand ERdj3 into cultured cells. Blockage of Radil by RNA interference abolishes the effect of ERdj3 and Prtg on the α5ß1-integrin, suggesting that Radil acts downstream of Prtg. Prtg-deficient R-CNCCs display fewer activated α5ß1-integrins in embryos, and these cells show reduced migratory ability in in vitro transwell assay. These results suggest that the inside-out activation of the α5ß1-integrin mediated by ERdj3/Prtg/Radil signaling is crucial for proper functions of R-CNCCs, and the deficiency of this pathway causes premature apoptosis of a subset of R-CNCCs and malformation of craniofacial structures.

Differential expression of protein kinases in cultured primary neurons derived from the cerebral cortex, hippocampus, and sympathetic ganglia.

Protein kinases play pivotal roles in the development of the nervous system. They are involved in almost every stage of neuronal development, from initial proliferation and differentiation of progenitor cells to pathfinding of neurites and formation of synapses. Activation of protein kinases is also critical for neuronal cell survival. To gain further insights into kinases in neural development, we studied the expression patterns of protein kinases in three cultured primary neurons by degenerate primer-based reverse transcription-polymerase chain reaction (PCR) and DNA sequencing, taking advantage of all known kinases containing a conserved catalytic domain. Our data demonstrated that the expression patterns of kinases in various cultured neurons are not only different from those of non-neural tissues, but also distinct among neurons derived from discrete origins. For example, FGF receptor 1 is predominantly expressed in hippocampal neurons. As this approach may be biased during PCR and cloning steps, an RNase protection assay was employed to verify the expression levels of six kinases in cultured neurons. Results from the RNase protection assay did generally confirm those obtained by the PCR-based method. However, quantitative nature of the latter was dependent on numbers of clones analyzed, and discrepancy of expression levels of kinases detected by the two methods was sometimes observed.

Activins as candidate cholinergic differentiation factors in vivo.

A number of cytokine families have been implicated in shaping neuronal survival, growth and gene expression. The neuropoietic and transforming growth factor-beta (TGF-beta) cytokines, in particular, have emerged as candidates for regulating the phenotype of sympathetic neurons. Culture studies have shown that neuropoietic cytokines (such as leukemia inhibitory factor, ciliary neurotrophic factor, oncostatin M, growth promoting activity) can induce the cholinergic enzyme, choline acetyltransferase (ChAT) and several neuropeptides, whereas certain members of the TGF-beta family (activin A, bone morphogenetic proteins-2 and -6) induce partially overlapping but distinct sets of transmitter and neuropeptide genes in sympathetic neurons. Since activins can induce ChAT in cultured neurons, we have investigated whether these cytokines are expressed by the appropriate cells and tissues to make them candidates for the cholinergic differentiation factor that is known to alter the phenotype of sympathetic neurons that innervate the sweat gland in the footpad in vivo. In-situ hybridization with the anti-sense probe for activin beta B specifically labels the sweat glands but not other tissues in the footpads of developing rats. Ribonuclease protection assays indicate that beta B as well as the other activin and inhibin subunit mRNAs are expressed by a number of tissues, including footpad, hairy skin and submaxillary gland. Homogenates of developing rat footpads, however, failed to induce the set of neuropeptide genes in cultured sympathetic neurons that is characteristic for activins, although neuropoietic cytokine activity was readily detectable in this assay. Thus, while activin beta B mRNA is expressed in the sweat gland, this tissue does not contain detectable activin protein as assayed by its ability to regulate neuronal gene expression. Moreover, activin subunit mRNAs are expressed by targets of noradrenergic sympathetic neurons in vivo, indicating that activin expression is not limited to targets of cholinergic neurons.

Depolarization differentially regulates the effects of bone morphogenetic protein (BMP)-2, BMP-6, and activin A on sympathetic neuronal phenotype.

As a first step in defining the role of the transforming growth factor-beta (TGF-beta) superfamily in the development of the sympathetic nervous system, we analyzed effects of several members of this family on neuronal gene expression in dissociated cell culture using a reverse transcription-polymerase chain reaction method. We found that, in addition to activin A, bone morphogenetic protein (BMP)-2 and BMP-6 also induce mRNAs for distinct sets of neuropeptides and neurotransmitter synthetic enzymes in sympathetic neurons. TGF-beta 1 and TGF-beta 3 are, however, without detectable effect in this assay. Surprisingly, we find that the patterns of neuropeptide genes induced by activin A, BMP-2, and BMP-6 are each affected differently by neuronal depolarization. Depolarization can either promote or block the effects of different cytokines on the same neuropeptide gene, and depolarization can either promote or block the effects of a given cytokine on different neuropeptide genes. This evidence suggests that neuronal activity may be a key mediator of cytokine modulation of neuronal gene expression.

Intratracheal injection of LPS and cytokines. V. LPS induces expression of LIF and LIF inhibits acute inflammation.

Lipopolysaccharide (LPS) injected into the trachea of rats was found to induce the secretion of leukemia inhibitory factor (LIF) into bronchoalveolar lavage (BAL) fluid with a maximum expression of LIF after 2-12 h. The acute pulmonary neutrophilic inflammation caused by the intratracheal injection of bacterial endotoxin (LPS) could be inhibited by the intratracheal coinjection of recombinant LIF. Compared with intratracheal injection of LPS alone, intratracheal coinjection of LIF and LPS decreases the number of BAL neutrophils obtained 6 h later by approximately 50% (P < 0.0001). LIF decreased the amount of the proinflammatory cytokine tumor necrosis factor (TNF), but not the amount of the anti-inflammatory cytokine interleukin (IL)-6, in the BAL fluid of LPS-injected rats. Similarly, intravenous LIF was found to decrease TNF expression, but increase IL-6 expression, in the serum of rats receiving intravenous LPS. Intravenous LIF, even in the absence of LPS, was found to cause IL-6 expression. In conclusion, intratracheal LPS initiates the secretion of endogenous LIF into the alveolar space where LIF may contribute to the downregulation of LPS-initiated acute neutrophilic inflammation by downregulating expression of TNF. LIF may down-regulate LPS-initiated TNF expression at least in part indirectly by upregulating expression of IL-6, a cytokine known to downregulate LPS-initiated TNF expression.

Neuropoietic cytokines and activin A differentially regulate the phenotype of cultured sympathetic neurons.

A number of cytokines sharing limited sequence homology have been grouped as a family because of partially overlapping biological activities, receptor subunit promiscuity, and the prediction of a shared secondary structure. Since several of these cytokines regulate gene expression and cell number in the nervous and hematopoietic systems, this specific group is termed the neuropoietic cytokine family. Using a reverse transcription-polymerase chain reaction-based assay system for monitoring the expression of multiple phenotypic markers in cultured sympathetic neurons, we present further evidence that, in addition to cholinergic differentiation factor/leukemia inhibitory factor and ciliary neurotrophic factor, oncostatin M, growth promoting activity, interleukin 6, and interleukin 11 belong in this family. In addition, one member of the transforming growth factor beta superfamily, activin A, shares a selective overlap with the neuropoietic family in the spectrum of neuropeptides that it induces in sympathetic neurons. The particular neuropeptides induced by activin A, however, demonstrate that the activity of this cytokine is distinct from that of the neuropoietic family. Twenty-six other cytokines and growth factors were without detectable activity in this assay.

A novel approach to screen for cytokine effects on neuronal gene expression.

We describe an assay based on reverse transcription-polymerase chain reaction to detect the expression of mRNAs for a variety of transmitter synthetic enzymes and neuropeptides present at low levels in primary neuronal cultures. The assay is specific for mRNA-derived templates and is not affected by the presence of genomic DNA. Using this method, we demonstrate that cholinergic differentiation factor/leukemia inhibitory factor (CDF/LIF) and ciliary neurotrophic factor (CNTF) induce mRNAs for choline acetyltransferase, somatostatin, substance P, vasoactive intestinal polypeptide, cholecystokinin, and enkephalin. The induction of cholecystokinin and enkephalin by CDF/LIF and CNTF had not been shown previously. These data illustrate that the assay can reproduce findings obtained with other methods, as well as provide the sensitivity necessary to produce new results. These results also extend the overlap of CDF/LIF and CNTF in controlling gene expression in cultured sympathetic neurons, supporting the idea that these cytokines may share receptor subunits and signal transduction pathways.

Further studies of the distribution of CDF/LIF mRNA.

Differentiation choices in the haemopoietic and nervous systems are controlled in part by instructive factors. The cholinergic differentiation factor (CDF, also known as leukaemia inhibitory factor, LIF) affects the development of cultured cells from both systems. To understand the role of CDF/LIF during normal development in vivo, we have begun to localize its mRNA in the late fetal and postnatal rat. Application of reverse transcriptase-polymerase chain reaction and RNase protection methods reveals that CDF/LIF mRNA levels are developmentally modulated in both haemopoietic and neural tissues. A target tissue of cholinergic sympathetic neurons, the footpads that contain the sweat glands, express high levels of this mRNA (relative to mRNA for actin and beta 2-microglobulin). Levels in targets of noradrenergic neurons are lower, but do undergo significant changes during development. Signals are also detected in selective regions of the adult brain, and in embryonic skeletal muscle. This finding in muscle may be significant for motor neurons, because CDF/LIF is a trophic factor for these neurons in culture. Embryonic liver, neonatal thymus and postnatal spleen express CDF/LIF mRNA, and expression in gut is the highest of all tissues examined. The selective tissue distribution and developmental modulation of CDF/LIF mRNA expression support a role for this factor in the normal development of several organ systems.

The cholinergic neuronal differentiation factor from heart cells is identical to leukemia inhibitory factor.

A protein secreted by cultured rat heart cells can direct the choice of neurotransmitter phenotype made by cultured rat sympathetic neurons. Structural analysis and biological assays demonstrated that this protein is identical to a protein that regulates the growth and differentiation of embryonic stem cells and myeloid cells, and that stimulates bone remodeling and acute-phase protein synthesis in hepatocytes. This protein has been termed D factor, DIA, DIF, DRF, HSFIII, and LIF. Thus, this cytokine, like IL-6 and TGF beta, regulates growth and differentiation in the embryo and in the adult in many tissues, now including the nervous system.