RDH10 is essential for synthesis of embryonic retinoic acid and is required for limb, craniofacial, and organ development

Regulation of patterning and morphogenesis during embryonic development depends on tissue-specific signaling by retinoic acid (RA), the active form of Vitamin A (retinol). The first enzymatic step in RA synthesis, the oxidation of retinol to retinal, is thought to be carried out by the ubiquitous or overlapping activities of redundant alcohol dehydrogenases. The second oxidation step, the conversion of retinal to RA, is performed by retinaldehyde dehydrogenases. Thus, the specific spatiotemporal distribution of retinoid synthesis is believed to be controlled exclusively at the level of the second oxidation reaction. In an N-ethyl-N-nitrosourea (ENU)-induced forward genetic screen we discovered a new midgestation lethal mouse mutant, called trex, which displays craniofacial, limb, and organ abnormalities. The trex phenotype is caused by a mutation in the short-chain dehydrogenase/reductase, RDH10. Using protein modeling, enzymatic assays, and mutant embryos, we determined that RDH10(trex) mutant protein lacks the ability to oxidize retinol to retinal, resulting in insufficient RA signaling. Thus, we show that the first oxidative step of Vitamin A metabolism, which is catalyzed in large part by the retinol dehydrogenase RDH10, is critical for the spatiotemporal synthesis of RA. Furthermore, these results identify a new nodal point in RA metabolism during embryogenesis.     

Mouse Ror2 receptor tyrosine kinase is required for the heart development and limb formation

BACKGROUNDS: A mouse receptor tyrosine kinase (RTK), mRor2, which belongs to the Ror-family of RTKs consisting of at least two structurally related members, is primarily expressed in the heart and nervous system during mouse development. To elucidate the function of mRor2, we generated mice with a mutated mRor2 locus. RESULTS: Mice with a homozygous mutation in mRor2 died just after birth, exhibiting dwarfism, severe cyanosis, and short limbs and tails. Whole-mount in situ hybridization analysis showed that mRor2 was expressed in the branchial arches, heart and limb/tailbuds, in addition to the developing nervous system. The mutants had cardiac septal defects, mainly a ventricular septal defect. In addition, an examination of the skeletal systems revealed that the mutants had shorter limbs, vertebrae and facial structure, with a particular defect in their distal portions, and that almost no calcification was observed in their distal limbs. Histological examination showed abnormalities in the chondrocytes. CONCLUSIONS: Our findings suggest that mRor2 plays essential roles in the development of the heart and in limb/tail formation, in particular cardiac septal formation and ossification of distal portions of limbs and tails.     

The mouse homolog of Drosophila Vasa is required for the development of male germ cells

Restricted expression of a mouse Vasa homolog gene (Mvh) expression is first detected in primordial germ cells (PGCs) after colonization of the genital ridges. Subsequently, Mvh is maintained until postmeiotic germ cells are formed. Here, we demonstrate that male mice homozygous for a targeted mutation of Mvh exhibit a reproductive deficiency. Male homozygotes produce no sperm in the testes, where premeiotic germ cells cease differentiation by the zygotene stage and undergo apoptotic death. In addition, the proliferation of PGCs that colonize homozygous male gonads is significantly hampered, and OCT-3/4 expression appears to be reduced. These results indicate that the loss of Mvh function causes a deficiency in the proliferation and differentiation of mouse male germ cells.     

Drosophila separase is required for sister chromatid separation and binds to PIM and THR

Drosophila PIM and THR are required for sister chromatid separation in mitosis and associate in vivo. Neither of these two proteins shares significant sequence similarity with known proteins. However, PIM has functional similarities with securin proteins. Like securin, PIM is degraded at the metaphase-to-anaphase transition and this degradation is required for sister chromatid separation. Securin binds and inhibits separase, a conserved cysteine endoprotease. Proteolysis of securin at the metaphase-to-anaphase transition activates separase, which degrades a conserved cohesin subunit, thereby allowing sister chromatid separation. To address whether PIM regulates separase activity or functions with THR in a distinct pathway, we have characterized a Drosophila separase homolog (SSE). SSE is an unusual member of the separase family. SSE is only about one-third the size of other separases and has a diverged endoprotease domain. However, our genetic analyses show that SSE is essential and required for sister chromatid separation during mitosis. Moreover, we show that SSE associates with both PIM and THR. Although our work shows that separase is required for sister chromatid separation in higher eukaryotes, in addition, it also indicates that the regulatory proteins have diverged to a surprising degree, particularly in Drosophila.     

Amnioserosa is required for dorsal closure in Drosophila.

Dorsal closure in the fruit fly Drosophila melanogaster is a complex morphogenetic process, driven by sequential signaling cascades and involving multiple forces, which contribute to cell movements and rearrangements as well as to changes in cell shape. During closure, lateral epidermal cells elongate along the dorsoventral axis and subsequently spread dorsally to cover the embryonic dorsal surface. Amnioserosal cells, which are the original occupants of the most dorsal position in the developing embryo, constrict during closure; thus, the increase in epidermal surface area is accommodated by a reduction in the amnioserosal surface area. Several of the epidermal requirements for closure have been established in functional assays. In contrast, amnioserosal requirements for closure have remained elusive, in part because laser ablation and clonal approaches are limited to only subsets of amnioserosal cells. Here, we report our use of the UAS-GAL4 system to target expression of the cell autonomous toxin Ricin-A to all cells of the amnioserosa. We show that ablation of the amnioserosa leads to clear defects in dorsal closure and, thus, directly demonstrate a role for the amnioserosa in dorsal closure. We also show that DJNK (Drosophila Jun N-terminal kinase) signaling, an epidermal trigger of closure, is unaffected by amnioserosal ablation. These data, together with our demonstration that amnioserosal ablated and Dpp signaling mutant embryos exhibit shared loss-of-function phenotypes, point to a requirement for the amnioserosa in dorsal closure that is downstream of Dpp, perhaps as part of a paracrine response to this signaling cascade.     

De novo CoA biosynthesis is required to maintain DNA integrity during development of the Drosophila nervous system

In a forward genetic screen in Drosophila melanogaster, aimed to identify genes required for normal locomotor function, we isolated dPPCS (the second enzyme of the Coenzyme A biosynthesis pathway). The entire Drosophila CoA synthesis route was dissected, annotated and additional CoA mutants were obtained (dPANK/fumble) or generated (dPPAT-DPCK). Drosophila CoA mutants suffer from neurodegeneration, altered lipid homeostasis and the larval brains display increased apoptosis. Also, de novo CoA biosynthesis is required to maintain DNA integrity during the development of the central nervous system. In humans, mutations in the PANK2 gene, the first enzyme in the CoA synthesis route, are associated with pantothenate kinase-associated neurodegeneration. Currently, the pathogenesis of this neurodegenerative disease is poorly understood. We provide the first comprehensive analysis of the physiological implications of mutations in the entire CoA biosynthesis route in an animal model system. Surprisingly, our findings reveal a major role of this conserved pathway in maintaining DNA and cellular integrity, explaining how impaired CoA synthesis during CNS development can elicit a neurodegenerative phenotype.     

A functional tonB gene is required for both utilization of heme and virulence expression by Haemophilus influenzae type b.

Haemophilus influenzae is nearly unique among facultatively anaerobic bacteria in its absolute requirement for exogenously supplied heme for aerobic growth. In this study, a mutant analysis strategy was used to facilitate identification of H. influenzae cell envelope components involved in the uptake of heme. Chemical mutagenesis was employed to produce a mutant of a nontypeable H. influenzae strain unable to utilize either protein-bound forms of heme or low levels of free heme. This mutant was transformed with a plasmid shuttle vector-based genomic library constructed from the same wild-type nontypeable H. influenzae strain, and a growth selection technique was used to obtain a recombinant clone that could utilize heme. Analysis of the DNA insert in the recombinant plasmid revealed the presence of several open reading frames, one of which encoded a 28-kDa protein with significant similarity to the TonB protein of Escherichia coli. This H. influenzae gene product was able to complement a tonB mutation in E. coli, allowing the E. coli tonB mutant to form single colonies on minimal medium containing vitamin B12. When this H. influenzae gene was inactivated by insertional mutagenesis techniques and introduced into the chromosome of wild-type strains of H. influenzae type b, the resultant transformants lost their abilities to utilize heme and produce invasive disease in an animal model. Genetic restoration of the ability to express this TonB homolog resulted in the simultaneous acquisition of both heme utilization ability and virulence. These results indicate that the H. influenzae TonB protein is required not only for heme utilization by this pathogen in vitro, but also for virulence of H. influenzae type b in an animal model.     

Drosophila Minus is required for cell proliferation and influences Cyclin E turnover

Turnover of cyclins plays a major role in oscillatory cyclin-dependent kinase (Cdk) activity and control of cell cycle progression. Here we present a novel cell cycle regulator, called minus, which influences Cyclin E turnover in Drosophila. minus mutants produce defects in cell proliferation, some of which are attributable to persistence of Cyclin E. Minus protein can interact physically with Cyclin E and the SCF Archipelago/Fbw7/Cdc4 ubiquitin–ligase complex. Minus does not affect dMyc, another known SCF^Ago substrate in Drosophila. We propose that Minus contributes to cell cycle regulation in part by selectively controlling turnover of Cyclin E.     

Drosophila CIAPIN1 homologue is required for follicle cell proliferation and survival

Background: The conserved cytokine‐induced apoptosis inhibitor‐1 (CIAPIN1) gene has been implicated in several processes, such as apoptosis, cell division, angiogenesis and Fe/S protein biogenesis. In this study, we identified the Drosophila CIAPIN1 homologue (D‐CIAPIN1) and studied its role in ovarian development. Results: We found that D‐CIAPIN1 is conserved as it can complement the nonviability of the yeast CIAPIN1‐deletion strain. Several D‐CIAPIN1 alleles were identified, including one allele in which that codon encoding the highly conserved twin cysteine CX₂C motif is mutated, demonstrating for the first time the importance of this motif to protein function. We demonstrated D‐CIAPIN1 is an essential gene required for ovarian development. We found that D‐CIAPIN1 female mutants are sterile, containing rudimentary ovaries. We noted a decrease in follicle cell numbers in D‐CIAPIN1 mutant egg chambers. We further demonstrated that the decrease in follicle cell numbers in D‐CIAPIN1 mutants is due to a reduced mitotic index and enhanced cell death. Conclusions: Our study reveals that D‐CIAPIN1 is essential for egg chamber development and is required for follicle cell proliferation and survival. Developmental Dynamics 242:731–737, 2013. © 2013 Wiley Periodicals, Inc.