Riho Meier

Nucleotide exchange factor RIC-8 is indispensable in mammalian early development.

The guanine nucleotide exchange factor RIC‐8 is a conserved protein essential for the asymmetric division in the early embryogenesis in different organisms. The function of RIC‐8 in mammalian development is not characterized so far. In this study we map the expression of RIC‐8 during the early development of mouse. To elucidate the RIC‐8 function we used Ric‐8−/− mutant embryos. The Ric‐8−/− embryos reach the gastrulation stage but do not develop further and die at E6.5‐E8.5. We characterized the Ric‐8−/− embryonic phenotype by morphological and marker gene analyses. The gastrulation is initiated in Ric‐8−/− embryos but their growth is retarded, epiblast and mesoderm disorganized. Additionally, the basement membrane is defective, amnion folding and the formation of allantois are interfered, also the cavitation. Furthermore, the orientation of the Ric‐8−/− embryo in the uterus was abnormal. Our study reveals that the activity of RIC‐8 protein is irreplaceable for the correct gastrulation of mouse embryo. Developmental Dynamics 239:3404–3415, 2010.

Expression of ric-8 (synembryn) gene in the nervous system of developing and adult mouse

Recent biochemical studies revealed that ric-8A encodes a guanine nucleotide exchange factor for a subset of Galpha proteins. Ric-8 is a key component of a signaling network in C. elegans that regulates neurotransmitter secretion and also plays a role in centrosome-mediated events during early embryogenesis. Here we show that during the early development in mice (E9.5-E12.0) ric-8 (synembryn) is expressed in the developing nervous system such as the cranial ganglia, neural tube, sympathetic chain and dorsal root ganglia. Ric-8 is also found in the lens, vomeronasal organ, and endolymphatic sac. In adult brain, it is expressed in the neocortex, hippocampus, and cerebellum as well as in the pineal gland and ependymal layer.

Heterozygous mice with Ric-8 mutation exhibit impaired spatial memory and decreased anxiety.

Ric-8 is a guanine nucleotide exchange factor for a subset of Galpha proteins and it is required to maintain Galpha(q) and the Galpha(s) pathways in functional state. In adult mice Ric-8 is expressed in regions involved in the regulation of behavior (neocortex, cingulate cortex and hippocampus). As Ric-8 is shown to regulate neuronal transmitter release, the aim of present study was to perform behavioral analysis of ric-8 mutant. Homozygous (-/-) ric-8 mutant mice are not viable and die in early embryonic development, therefore for behavioral analysis heterozygous (+/-) ric-8 mutant mice were used. We found decreased anxiety of ric-8 heterozygous mice in light-dark compartment test where mutant mice significantly avoided the light compartment. In spatial learning paradigm (Morris water maze) the performance of ric-8 (+/-) mice was impaired. Namely, in the reversal test, ric-8 (+/-) mice exhibited significant delay to find the hidden platform compared to wild-type (wt) littermates. We did not find differences in the behavioral tests reflecting the motor abilities of mice (motor activity, rota-rod). Therefore, described alterations seem to be specific for anxiety and spatial learning. Based on these results we can conclude the importance of ric-8 in the regulation of memory and emotional behavior.

Lack of Gata3 results in conotruncal heart anomalies in mouse.

The transcription factor Gata3 is an important regulator of the development of thymus, the nervous system, ear, kidney, and adrenal glands. This study analyzes the role of Gata3 in the developing heart using a mouse strain containing an nlsLacZ reporter gene fused in frame to the Gata3 gene by homologous recombination. Using in situ hybridization, RT-PCR and Gata3-LacZ histochemistry, Gata3 expression was shown in various cardiac structures up to newborn stage. During looping stages (E9.5-E11.5) Gata3-LacZ activity recapitulated endogenous Gata3 and was abundantly expressed in the endocardial ridges and endothelium of distal outflow tract. Strong reporter gene expression was also noted in the mesenchyme of ventral branchial arches, and in the epithelium. In the atrioventricular canal expression was relatively lower. In the four-chambered heart stages (E13.5-E17.5) the LacZ-staining did not recapitulate the endogenous Gata3 transcript and showed rather lineage tracing of formerly Gata3-expressing cells in the hearts. beta-Galactosidase activity was detected in the cusps of semilunar valves, aorta, pulmonary trunk, innominate and common carotid arteries, and faintly in the atrioventricular valves. Gata3-null embryos die normally between E11 and E12. Pharmacological treatment with sympathomimetic beta-adrenergic receptor agonist lengthens the survival up to E18 when malformations of the heart such as ventricular septal defect (VSD), double-outlet of right ventricle (DORV), anomalies of the aortic arch (AAA) and persistent truncus arteriosus (PTA) were detected. The specified malformations correlate with the normal developmental pattern of Gata3-LacZ expression. The short outflow tract and insufficient rotation of truncus arteriosus during looping stages might be the main reasons underlying these malformations.

Ablation of RIC8A function in mouse neurons leads to a severe neuromuscular phenotype and postnatal death.

Resistance to inhibitors of cholinesterase 8 (RIC8) is a guanine nucleotide exchange factor required for the intracellular regulation of G protein signalling. RIC8 activates different Gα subunits via non-canonical pathway, thereby amplifying and prolonging the G protein mediated signal. In order to circumvent the embryonic lethality associated with the absence of RIC8A and to study its role in the nervous system, we constructed Ric8a conditional knockout mice using Cre/loxP technology. Introduction of a synapsin I promoter driven Cre transgenic mouse strain (SynCre) into the floxed Ric8a (Ric8a F/F) background ablated RIC8A function in most differentiated neuron populations. Mutant SynCre +/- Ric8 lacZ/F mice were born at expected Mendelian ratio, but they died in early postnatal age (P4-P6). The mutants exhibited major developmental defects, like growth retardation and muscular weakness, impaired coordination and balance, muscular spasms and abnormal heart beat. Histological analysis revealed that the deficiency of RIC8A in neurons caused skeletal muscle atrophy and heart muscle hypoplasia, in addition, the sinoatrial node was misplaced and its size reduced. However, we did not observe gross morphological changes in brains of SynCre +/- Ric8a lacZ/F mutants. Our results demonstrate that in mice the activity of RIC8A in neurons is essential for survival and its deficiency causes a severe neuromuscular phenotype.

Wfs1- deficient rats develop primary symptoms of Wolfram syndrome: insulin-dependent diabetes, optic nerve atrophy and medullary degeneration

Wolfram syndrome (WS) is a rare autosomal-recessive disorder that is caused by mutations in the WFS1 gene and is characterized by juvenile-onset diabetes, optic atrophy, hearing loss and a number of other complications. Here, we describe the creation and phenotype of Wfs1 mutant rats, in which exon 5 of the Wfs1 gene is deleted, resulting in a loss of 27 amino acids from the WFS1 protein sequence. These Wfs1-ex5-KO232 rats show progressive glucose intolerance, which culminates in the development of diabetes mellitus, glycosuria, hyperglycaemia and severe body weight loss by 12 months of age. Beta cell mass is reduced in older mutant rats, which is accompanied by decreased glucose-stimulated insulin secretion from 3 months of age. Medullary volume is decreased in older Wfs1-ex5-KO232 rats, with the largest decreases at the level of the inferior olive. Finally, older Wfs1-ex5-KO232 rats show retinal gliosis and optic nerve atrophy at 15 months of age. Electron microscopy revealed axonal degeneration and disorganization of the myelin in the optic nerves of older Wfs1-ex5-KO232 rats. The phenotype of Wfs1-ex5-KO232 rats indicates that they have the core symptoms of WS. Therefore, we present a novel rat model of WS.

A novel hypothesis for histone-to-protamine transition in Bos taurus spermatozoa.

DNA compaction with protamines in sperm is essential for successful fertilization. However, a portion of sperm chromatin remains less tightly packed with histones, which genomic location and function remain unclear. We extracted and sequenced histone-associated DNA from sperm of nine ejaculates from three bulls. We found that the fraction of retained histones varied between samples, but the variance was similar between samples from the same and different individuals. The most conserved regions showed similar abundance across all samples, whereas in other regions, their presence correlated with the size of histone fraction. This may refer to gradual histone–protamine transition, where easily accessible genomic regions, followed by the less accessible regions are first substituted by protamines. Our results confirm those from previous studies that histones remain in repetitive genome elements, such as centromeres, and added new findings of histones in rRNA and SRP RNA gene clusters and indicated histone enrichment in some spermatogenesis-associated genes, but not in genes of early embryonic development. Our functional analysis revealed significant overrepresentation of cGMP-dependent protein kinase G (cGMP-PKG) pathway genes among histone-enriched genes. This pathway is known for its importance in pre-fertilization sperm events. In summary, a novel hypothesis for gradual histone-to-protamine transition in sperm maturation was proposed. We believe that histones may contribute structural information into early embryo by epigenetically modifying centromeric chromatin and other types of repetitive DNA. We also suggest that sperm histones are retained in genes needed for sperm development, maturation and fertilization, as these genes are transcriptionally active shortly prior to histone-to-protamine transition.

Deletion of RIC8A in neural precursor cells leads to altered neurogenesis and neonatal lethality of mouse

RIC8A is a noncanonical guanine nucleotide exchange factor for a subset of Gα subunits. RIC8A has been reported in different model organisms to participate in the control of mitotic cell division, cell signalling, development and cell migration. Still, the function of RIC8A in the mammalian nervous system has not been sufficiently analysed yet. Adult mice express RIC8A in the brain regions involved in the regulation of memory and emotional behaviour. To elucidate the role of RIC8A in mammalian neurogenesis we have inactivated Ric8a in neural precursor cells using Cre/Lox system. As a result, the conditional knockout mice were born at expected Mendelian ratio, but died or were cannibalized by their mother within 12 h after birth. The cerebral cortex of the newborn Nes;Ric8aCKO mice was thinner compared to littermates and the basement membrane was discontinuous, enabling migrating neurons to invade to the marginal zone. In addition, the balance between the planar and oblique cell divisions was altered, influencing the neuron production. Taken together, RIC8A has an essential role in the development of mammalian nervous system by maintaining the integrity of pial basement membrane and modulating cell division.

RIC8A is essential for the organisation of actin cytoskeleton and cell-matrix interaction

&NA; RIC8A functions as a chaperone and guanine nucleotide exchange factor for a subset of G protein &agr; subunits. Multiple G protein subunits mediate various signalling events that regulate cell adhesion and migration and the involvement of RIC8A in some of these processes has been demonstrated. We have previously shown that the deficiency of RIC8A causes a failure in mouse gastrulation and neurogenesis – major events in embryogenesis that rely on proper association of cells with the extracellular matrix (ECM) and involve active cell migration. To elaborate on these findings, we used Ric8a‐/‐ mouse embryonic stem cells and Ric8a‐deficient mouse embryonic fibroblasts, and found that RIC8A plays an important role in the organisation and remodelling of actin cytoskeleton and cell‐ECM association. Ric8a‐deficient cells were able to attach to different ECM components, but were unable to spread correctly, and did not form stress fibres or focal adhesion complexes. We also found that the presence of RIC8A is necessary for the activation of &bgr;1 integrins and integrin‐mediated cell migration. HighlightsRIC8A‐deficiency compromised cell spreading on the extracellular matrix.Focal adhesion complexes and stress fibres did not form in RIC8A‐deficient cells.The deficiency of RIC8A altered cell migration on &bgr;1 integrin specific substrates.RIC8A seems to affect the activity of &bgr;1 integrins.

Expression Pattern and Localization Dynamics of Guanine Nucleotide Exchange Factor RIC8 during Mouse Oogenesis

Targeting of G proteins to the cell cortex and their activation is one of the triggers of both asymmetric and symmetric cell division. Resistance to inhibitors of cholinesterase 8 (RIC8), a guanine nucleotide exchange factor, activates a certain subgroup of G protein α-subunits in a receptor independent manner. RIC8 controls the asymmetric cell division in Caenorhabditis elegans and Drosophila melanogaster, and symmetric cell division in cultured mammalian cells, where it regulates the mitotic spindle orientation. Although intensely studied in mitosis, the function of RIC8 in mammalian meiosis has remained unknown. Here we demonstrate that the expression and subcellular localization of RIC8 changes profoundly during mouse oogenesis. Immunofluorescence studies revealed that RIC8 expression is dependent on oocyte growth and cell cycle phase. During oocyte growth, RIC8 is abundantly present in cytoplasm of oocytes at primordial, primary and secondary preantral follicle stages. Later, upon oocyte maturation RIC8 also populates the germinal vesicle, its localization becomes cell cycle dependent, and it associates with chromatin and the meiotic spindle. After fertilization, RIC8 protein converges to the pronuclei and is also detectable at high levels in the nucleolus precursor bodies of both maternal and paternal pronucleus. During first cleavage of zygote RIC8 localizes in the mitotic spindle and cell cortex of forming blastomeres. In addition, we demonstrate that RIC8 co-localizes with its interaction partners Gαi1/2:GDP and LGN in meiotic/mitotic spindle, cell cortex and polar bodies of maturing oocytes and zygotes. Downregulation of Ric8 by siRNA leads to interferred translocation of Gαi1/2 to cortical region of maturing oocytes and reduction of its levels. RIC8 is also expressed at high level in female reproductive organs e.g. oviduct. Therefore we suggest a regulatory function for RIC8 in mammalian gametogenesis and fertility.