Evidence for crucial role of hindgut expansion in directing proper migration of primordial germ cells in mouse early embryogenesis

During mouse gastrulation, primordial germ cells (PGCs) become clustered at the base of the allantois and move caudally into the hindgut endoderm before entering the genital ridges. The precise roles of endoderm tissues in PGC migration, however, remain unclear. By using Sox17 mutants with a specific endoderm deficiency, we provide direct evidence for the crucial role of hindgut expansion in directing proper PGC migration. In Sox17-null embryos, PGCs normally colonize in the allantois and then a small front-row population of PGCs moves properly into the most posterior gut endoderm. Defective hindgut expansion, however, causes the failure of further lateral PGC movement, resulting in the immobilization of PGCs in the hindgut entrance at the later stages. In contrast, the majority of the remaining PGCs moves into the visceral endoderm layer, but relocate outside of the embryonic gut domain. This leads to a scattering of PGCs in the extraembryonic yolk sac endoderm. This aberrant migration of Sox17-null PGCs can be rescued by the supply of wildtype hindgut cells in chimeric embryos. Therefore, these data indicate that hindgut morphogenic movement is crucial for directing PGC movement toward the embryonic gut side, but not for their relocation from the mesoderm into the endoderm.     

Medaka vasa is required for migration but not survival of primordial germ cells

vasa is essential for germline development. However, the precise processes in which vasa involves vary considerably in diverse animal phyla. Here we show that vasa is required for primordial germ cell (PGC) migration in the medakafish. vasa knockdown by two morpholinos led to the PGC migration defect that was rescued by coinjection of vasa RNA. Interestingly, vasa knockdown did not alter the PGC number, identity, proliferation and motility even at ectopic locations. We established a cell culture system for tracing PGCs at the single cell level in vitro. In this culture system, control and morpholino-injected gastrulae produced the same PGC number and the same time course of PGC survival. Importantly, vasa-depleted PGCs in culture had similar motility and locomotion to normal PGCs. Expression patterns of wt1a, sdf1b and cxcr4b in migratory tissues remained unchanged by vasa knockdown. By chimera formation we show that PGCs from vasa-depleted blastulae failed to migrate properly in the normal environment, whereas control PGCs migrated normally in vasa-disrupted embryos. Furthermore, ectopic PGCs in vasa-depleted embryos also retained all the PGC properties examined. Taken together, medaka vasa is cell-autonomously required for PGC migration, but dispensable to PGC proliferation, motility, identity and survival.     

BAX-mediated cell death affects early germ cell loss and incidence of testicular teratomas in Dnd1 mice

A homozygous nonsense mutation (Ter) in murine Dnd1 (Dnd1^Ter/Ter) results in a significant early loss of primordial germ cells (PGCs) prior to colonization of the gonad in both sexes and all genetic backgrounds tested. The same mutation also leads to testicular teratomas only on the 129Sv/J background. Male mutants on other genetic backgrounds ultimately lose all PGCs with no incidence of teratoma formation. It is not clear how these PGCs are lost or what factors directly control the strain-specific phenotype variation. To determine the mechanism underlying early PGC loss we crossed Dnd1^Ter/Ter embryos to a Bax-null background and found that germ cells were partially rescued. Surprisingly, on a mixed genetic background, rescued male germ cells also generated fully developed teratomas at a high rate. Double-mutant females on a mixed background did not develop teratomas, but were fertile and produced viable off-spring. However, when Dnd1^Ter/Ter XX germ cells developed in a testicular environment they gave rise to the same neoplastic clusters as mutant XY germ cells in a testis. We conclude that BAX-mediated apoptosis plays a role in early germ cell loss and protects from testicular teratoma formation on a mixed genetic background.     

Medaka dead end encodes a cytoplasmic protein and identifies embryonic and adult germ cells

dead end (dnd) was identified in zebrafish as a gene encoding an RNA-binding protein essential for primordial germ cell (PGC) development and gametogenesis in vertebrates. The adult dnd RNA expression has been restricted to the ovary in Xenopus or to the testis in mouse. Its protein product is nuclear in chicken germ cells but both cytosolic and nuclear in mouse cell cultures. Here we report the cloning and expression pattern of Odnd, the medakafish (Oryzias latipes) dnd gene. Sequence comparison, gene structure, linkage analysis and expression demonstrate that Odnd encodes the medaka Dnd orthologue. A systematic comparison of Dnd proteins from five fishes and tetrapod representatives led to the identification of five previously unidentified conserved regions besides the RNA recognition motif. The Odnd RNA is maternally supplied and preferentially segregated with PGCs. Its adult expression occurs in both sexes and is restricted to germ cells. In the testis, Odnd is abundant in spermatogonia and meiotic cells but absent in sperm. In the ovary, Odnd RNA persists throughout oogenesis. Furthermore, we developed a dual color fluorescent in situ hybridization procedure allowing for precise comparisons of expression and distribution patterns between two genes in medaka embryos and adult tissues. Importantly, this procedure co-localized Odnd and Ovasa in testicular germ cells and PGCs. Surprisingly, by cell transfection and embryo RNA injection we show that ODnd is cytoplasmic in cell cultures, cleavage embryos and PGCs. Therefore, medaka dnd encodes a cytoplasmic protein and identifies embryonic and adult germ cells of both sexes.     

Time-lapse analysis reveals different modes of primordial germ cell migration in the medaka Oryzias latipes

Previous studies have shown that medaka primordial germ cells (PGC) are first distinguishable by olvas expression during late gastrulation, and that they migrate to the gonadal region through the lateral plate mesoderm. Here, we demonstrate that medaka nanos expression marks the germ line at early gastrulation stage. By marking the germ line with green fluorescent protein (GFP) fused to the nanos 3' untranslated region, we were able to visualize the behavior of PGC using time-lapse imaging. We show that there are three distinct modes of PGC migration that function at different stages of development. At early gastrulation stage, PGC actively migrate towards the marginal zone, a process that requires the function of a chemokine receptor, CXCR4. However, at late gastrulation stage, PGC change the mode and direction of their movement, as they are carried towards the midline along with somatic cells undergoing convergent movements. After aligning bilaterally, PGC actively migrate to the posterior end of the lateral plate mesoderm. This posterior movement depends on the activity of both HMGCoAR and a ligand of CXCR4, SDF-1a. These results demonstrate that PGC undergo different modes of migration to reach the prospective gonadal region of the embryo.     

Analysis of SDF-1/CXCR4 signaling in primordial germ cell migration and survival or differentiation in Xenopus laevis

Directional migration of primordial germ cells (PGCs) toward future gonads is a common feature in many animals. In zebrafish, mouse and chicken, SDF-1/CXCR4 chemokine signaling has been shown to have an important role in PGC migration. In Xenopus, SDF-1 is expressed in several regions in embryos including dorsal mesoderm, the target region that PGCs migrate to. CXCR4 is known to be expressed in PGCs. This relationship is consistent with that of more well-known animals. Here, we present experiments that examine whether chemokine signaling is involved in PGC migration of Xenopus. We investigate: (1) Whether injection of antisense morpholino oligos (MOs) for CXCR4 mRNA into vegetal blastomere containing the germ plasm or the precursor of PGCs disturbs the migration of PGCs? (2) Whether injection of exogenous CXCR4 mRNA together with MOs can restore the knockdown phenotype? (3) Whether the migratory behavior of PGCs is disturbed by the specific expression of mutant CXCR4 mRNA or SDF-1 mRNA in PGCs? We find that the knockdown of CXCR4 or the expression of mutant CXCR4 in PGCs leads to a decrease in the PGC number of the genital ridges, and that the ectopic expression of SDF-1 in PGCs leads to a decrease in the PGC number of the genital ridges and an increase in the ectopic PGC number. These results suggest that SDF-1/CXCR4 chemokine signaling is involved in the migration and survival or in the differentiation of PGCs in Xenopus.     

Killing the messenger: The role of CXCR7 in regulating primordial germ cell migration

Primordial Germ Cell (PGC) migration in zebrafish is guided by SDF-1a. Binding of this chemokine to its receptor CXCR4b activates downstream signalling cascades leading to cell polarization and directed migration towards the attractant source. Despite the detailed information available concerning the role of SDF-1 in guiding the PGCs to their targets, little was known regarding the molecular mechanisms controlling the distribution of SDF-1a within the tissue. We have recently shown that the activity of a second SDF-1/CXCL12 receptor, CXCR7 is crucial for proper migration of PGCs. Although CXCR4 and CXCR7 are structurally related and serve as receptors for the same ligand, they appear to serve very different functions during PGC migration. Here we discuss a model according to which CXCR4b translates the polarized distribution of SDF-1 into directed PGC migration, while CXCR7 acts as a high-affinity decoy receptor and facilitates the migration of PGCs by shaping the distribution of the chemokine in the environment.Key words: cell migration, CXCR4, CXCR7, SDF-1, chemokine, chemotaxisChemokine-guided cell migration is central for many processes in normal development and homeostasis (e.g., embryogenesis) as well as in pathological conditions (e.g., inflammation). Zebrafish primordial germ cells (PGCs) serve as a useful model for studying chemokine-controlled cell migration in vivo as the migrating PGCs sense and respond to the dynamic distribution of the chemokine SDF-1a through its receptor CXCR4b.^1,2Recent reports identified CXCR7 as a receptor for SDF-1^3,4 that controls processes such as cell adhesion, survival and tumor progression. A role for this receptor in regulating cell migration during development was demonstrated in the zebrafish lateral line.^5,6 The zebrafish lateral line primordium migrates directionally on a stripe of uniform sdf-1a expression to deposit a set of sensory organs along the fish tail. While the authors raised the hypothesis that antagonistic interactions between CXCR4b and CXCR7 polarize the developing organ to allow its migration, the precise function of CXCR7 in this process remained unclear.To address this question in an in vivo context, we examined the role CXCR7 plays in zebrafish PGC migration.⁷ Our experiments revealed that knockdown of cxcr7 translation using morpholino antisense oligo nucleotides results in impaired polarity and aberrant migration of PGCs. Unlike cxcr4b, cxcr7 is not specifically expressed in the PGCs but is initially uniformly distributed throughout the embryo. Furthermore, in contrast to activity of CXCR4, CXCR7 function was found to be required in tissues surrounding the migrating cells rather than in the PGCs themselves.To examine the function of CXCR7 in somatic cells we determined the subcellular localization of the protein as compared with that of CXCR4b and SDF-1a. Interestingly, while CXCR4b is predominantly localized to the plasma membrane, CXCR7 is found primarily in intracellular structures. The fact that SDF-1α and CXCR7 colocalized in the cell and that SDF-1α was found in vesicles that contained the lysosomal marker LAMP-1 suggested that the prime role of CXCR7 is to bind and internalize SDF-1a thereby controlling the level of the diffusible chemokine in the extracellular space. Indeed, observing PGCs expressing CXCR4b on their membrane we detected strong receptor internalization when CXCR7 function was knocked down. The enhanced internalization, a typical response to high levels of SDF-1a⁸ could be reversed by concomitant removal of SDF-1.These findings provided an explanation for the CXCR7 knock-down phenotype as abnormally high levels of SDF-1a in the environment have been shown before to interfere with cell motility.^1,2 Indeed, PGCs in CXCR7 knocked-down embryos displayed strong inhibition of motility manifested in short migration tracks—a phenotype that could be reversed by simultaneous removal of CXCR7 and SDF-1.The implication of the results presented above is that the sole function of CXCR7 in the context of PGC migration is ligand sequestration. Consistent with this idea, two typical signalling responses acting downstream of chemokine receptors namely, elevation of intracellular calcium levels and PI3K activation^9–13 were not altered in cells knocked down for CXCR7. Thus, consistent with other reports,^4,14 our results imply that CXCR7 signalling is not required for PGC migration.An important outstanding question concerns the molecular basis for the dramatic difference between the activity of CXCR4 and that of CXCR7. Defining domains and amino acids responsible for this difference would provide extensive information regarding chemokine receptor signalling and trafficking within the cell. Whereas random mutagenesis and generation of various CXCR4-CXCR7 chimeric molecules might provide an answer to this question, it is tempting to speculate that known protein motifs are responsible for the differences between the two receptors. For example, an obvious candidate region is that around its DRY motif,¹⁴ a motif within the second intracellular loop that is important for Gprotein coupling and signalling.¹⁵ Whereas uncoupling downstream signalling in the case of CXCR7 is an interesting research avenue, other non-mutually exclusive options should be examined (Fig. 1). For example, CXCR7 could possess domains that facilitate interaction with components that enhance internalization. Such an interaction could remove the receptor from the location where it normally interacts with the signalling machinery, while effectively internalizing SDF-1a.Open in a separate windowFigure 1Proposed model for differential functions of CXCR4b and CXCR7. (A) CXCR4b signalling in PGCs controls cell polarization and directional migration in response to SDF-1a binding (squares), through interaction with G-proteins and elevation of calcium levels. (B) Binding of SDF-1a by CXCR7 does not elicit signalling. Endocytosis of the lignad-bound CXCR7 leads to sequestration and degradation of SDF-1a in the somatic environment.Taken together, we show that proper PGC migration requires a mechanism to remove the guidance cue thereby allowing the formation of an informative chemotactic gradient. It would be very interesting to examine whether the paradigm demonstrated for the PGC migration model applies for other chemokine-guided events in development and disease.     

Control of cell migration in the development of the posterior lateral line: antagonistic interactions between the chemokine receptors CXCR4 and CXCR7/RDC1

Background  

The formation of the posterior lateral line of teleosts depends on the migration of a primordium that originates near the otic vesicle and moves to the tip of the tail. Groups of cells at the trailing edge of the primordium slow down at regular intervals and eventually settle to differentiate as sense organs. The migration of the primordium is driven by the chemokine SDF1 and by its receptor CXCR4, encoded respectively by the genes sdf1a and cxcr4b. cxcr4b is expressed in the migrating cells and is down-regulated in the trailing cells of the primordium. sdf1a is expressed along the path of migration. There is no evidence for a gradient of sdf1a expression, however, and the origin of the directionality of migration is not known.     

Map-based cloning of a novel rice cytochrome P450 gene CYP81A6 that confers resistance to two different classes of herbicides

Development of hybrid rice has greatly contributed to increased yields during the past three decades. Two bentazon-lethal mutants 8077S and Norin8m are being utilized in developing new hybrid rice systems. When the male sterile lines are developed in such a mutant background, the problem of F1 seed contamination by self-seeds from the sterile lines can be solved by spraying bentazon at seedling stage. We first determined the sensitivity of the mutant plants to bentazon. Both mutants showed symptoms to bentazon starting from 100 mg/l, which was about 60-fold, lower than the sensitivity threshold of their wild-type controls. In addition, both mutants were sensitive to sulfonylurea-type herbicides. The locus for the mutant phenotype is bel for 8077S and bsl for Norin8m. Tests showed that the two loci are allelic to each other. The two genes were cloned by map-based cloning. Interestingly, both mutant alleles had a single-base deletion, which was confirmed by PCR-RFLP. The two loci are renamed bel ^a (for bel) and bel ^b (for bsl). The wild-type Bel gene encodes a novel cytochrome P450 monooxgenase, named CYP81A6. Analysis of the mutant protein sequence also revealed the reason for bel ^a being slightly tolerant than bel ^b . Introduction of the wild-type Bel gene rescued the bentazon- and sulfonylurea-sensitive phenotype of bel ^a mutant. On the other hand, expression of antisense Bel in W6154S induced a mutant phenotype. Based on these results we conclude that the novel cytochrome P450 monooxygenase CYP81A6 encoded by Bel confers resistance to two different classes of herbicides. Gang Pan and Xianyin Zhang contributed equally to this work.     

cell clones and pattern formation: Studies onsevenless,a mutant ofDrosophila melanogaster

Summary sev ^LY3,the only existing allele at thesev locus (1–33,2±0,2), behaves as strongly hypomorph or even as amorph. Ommatidia in asev compound eye have only seven receptor cells, the position of the R7 pattern element being vacant. Various criteria showing that the missing cell is R7 have been verified. These include (i) anatomical characteristics ofsev ommatidia; (ii) behaviour of central R cells insev rdgB double mutants; (iii) medullary projection of central R cell axons; and (iv) mitotic pattern ofsev imaginal discs. The analysis of morphogeneticsev-sev ⁺ mosaics has shown thatsev is expressed autonomously by R7 cells, indicating that thesev phenotype is not due to asev genotype of ommatidial pattern elements other than R7. The study of third instarsev imaginal discs has not brought any direct evidence for death of clustered presumptive R7 cells; however, clonal analysis of the developingsev compound eye has given evidence of developmental parameters comparable to those ofsev ⁺, therefore favouring the hypothesis that R7 cells die insev mutants. On the other hand,sev ⁺ seems to be required for the determination of the R7 cells, since thesev phenotype cannot be uncovered during the last mitoses of heterozygous mutant cells.     

Xmrk‐induced melanoma progression is affected by Sdf1 signals through Cxcr7

Chemokine signals mediated by Sdf1/Cxcl12 through the chemokine receptor Cxcr4 are thought to play an instructive role in tumor migration and organ‐specific metastasis. We have used a small aquarium fish model to contribute to a better understanding of how the course of melanoma development is influenced by Sdf1 signals in vivo. We studied oncogene‐induced skin tumor appearance and progression in the transgenic medaka (Oryzias latipes) melanoma model. Similar to humans, invasive medaka melanomas show increased levels of sdf1, cxcr4, and cxcr7 gene expression. Stable transgenic fish lines overexpressing sdf1 exclusively in pigment cells showed a reduction in melanoma appearance and progression. Remarkably, diminished levels of functional Cxcr7, but not of Cxcr4b, resulted in strongly reduced melanoma invasiveness and a repression of melanoma. Our results thereby indicate that Sdf1 signals via Cxcr7 are able to constrain melanoma growth in vivo and that these signals influence tumor outcome.     

Expression of five frizzleds during zebrafish craniofacial development

Wnt/Planar Cell Polarity (PCP) signaling is critical for proper animal development. While initially identified in Drosophila, this pathway is also essential for the proper development of vertebrates. Zebrafish mutants, defective in the Wnt/PCP pathway, frequently display defects in convergence and extension gastrulation movements and additional later abnormalities including problems with craniofacial cartilage morphogenesis. Although multiple Frizzled (Fzd) homologues, Wnt receptors, were identified in zebrafish, it is unknown which Fzd plays a role in shaping the early larvae head skeleton. In an effort to determine which Frizzleds are involved in this process, we analyzed the expression of five zebrafish frizzled homologues fzd2, 6, 7a, 7b, and 8a from 2–4 days post-fertilization (dpf). During the analyzed developmental time points fzd2 and fzd6 are broadly expressed throughout the head, while the expression of fzd7a, 7b and 8a is much more restricted. Closer examination revealed that fzd7b is expressed in the neural crest and the mesodermal core of the pharyngeal arches and in the chondrocytes of newly stacked craniofacial cartilage elements. However, fzd7a is only expressed in the neural crest of the pharyngeal arches and fzd8a is expressed in the pharyngeal endoderm.     

A novel function for KIF13B in germ cell migration

Primordial germ cell (PGC) development in Xenopus embryos relies on localised maternal determinants. We report on the identification and functional characterisation of such one novel activity, a germ plasm associated mRNA encoding for the Xenopus version of a kinesin termed KIF13B. Modulations of xKIF13B function result in germ cell mismigration and in reduced numbers of such cells. PGCs explanted from Xenopus embryos form bleb-like protrusions enriched in PIP3. Knockdown of xKIF13B results in inhibition of blebbing and PIP3 accumulation. Interference with PIP3 synthesis leads to PGC mismigration in vivo and in vitro. We propose that xKIF13B function is linked to polarized accumulation of PIP3 and directional migration of the PGCs in Xenopus embryos.     

RagA和Nprl2在果蝇肠道发育中的调节作用关系

动物胃肠道是食物消化和营养吸收器官,对机体健康至关重要。果蝇与哺乳动物的肠道在细胞组成、遗传调控等方面高度相似,是研究肠道发育的良好模型。体外培养细胞中的研究发现,Nprl2通过作用于Rag GTPase,抑制雷帕霉素靶点复合物1(target of rapamycin complex 1,TORC1)的活性,参与细胞代谢的调节。前期报道nprl2突变果蝇具有前胃增大、消化能力降低等肠道衰老相关表型。但对于Nprl2是否通过Rag GTPase调控肠道发育等方面尚不清楚。为了探究Rag GTPase在Nprl2调控果蝇肠道发育中的作用,本研究利用遗传杂交结合免疫荧光等方法对RagA敲减和nprl2突变果蝇的肠道形态、肠道细胞组成等方面进行研究。发现单独敲减RagA可以引起肠变粗、前胃增大等表型,敲减RagA能挽救nprl2突变体中肠道变细、分泌型细胞减少的表型,但并不能挽救nprl2突变体中前胃增大的表型。以上结果表明,RagA在肠道发育中发挥重要作用,Nprl2通过作用于Rag GTPase调节肠道细胞分化和肠道形态,但Nprl2对前胃发育和肠道的消化功能的调节可能通过不依赖于Rag GTPase的机制实现。     

Formation and cultivation of medaka primordial germ cells

Primordial germ cell (PGC) formation is pivotal for fertility. Mammalian PGCs are epigenetically induced without the need for maternal factors and can also be derived in culture from pluripotent stem cells. In egg-laying animals such as Drosophila and zebrafish, PGCs are specified by maternal germ plasm factors without the need for inducing factors. In these organisms, PGC formation and cultivation in vitro from indeterminate embryonic cells have not been possible. Here, we report PGC formation and cultivation in vitro from blastomeres dissociated from midblastula embryos (MBEs) of the fish medaka (Oryzias latipes). PGCs were identified by using germ-cell-specific green fluorescent protein (GFP) expression from a transgene under the control of the vasa promoter. Embryo perturbation was exploited to study PGC formation in vivo, and dissociated MBE cells were cultivated under various conditions to study PGC formation in vitro. Perturbation of somatic development did not prevent PGC formation in live embryos. Dissociated MBE blastomeres formed PGCs in the absence of normal somatic structures and of known inducing factors. Most importantly, under culture conditions conducive to stem cell derivation, some dissociated MBE blastomeres produced GFP-positive PGC-like cells. These GFP-positive cells contained genuine PGCs, as they expressed PGC markers and migrated into the embryonic gonad to generate germline chimeras. Our data thus provide evidence for PGC preformation in medaka and demonstrate, for the first time, that PGC formation and derivation can be obtained in culture from early embryos of medaka as a lower vertebrate model.     

Maintenance of plasmids in HU and 1HF mutants of Escherichia coli

Summary Complementation and sequencing analyses revealed that the hopD mutants, which could not support stable maintenance of mini-F plasmids (Niki et al. 1988), had mutations in the hupB gene, and that the hopD410 mutation was an ochre mutation at the 5th Gln position of HU-1. Maintenance and stability of various plasmids, mini-P1 plasmids, mini-F plasmids, and oriC plasmids, were studied in the hupA and hupB mutants (HU mutants), and himA and hip mutants (IHF mutants). Mini-P1 plasmids and mini-F plasmids could not be introduced into the hupA-hupB double deletion mutant. Replication of mini-F plasmids was partially inhibited in the hupB mutants, including the hupB and hopD(hupB) mutants, whereas replication of oriC plasmids was not significantly affected even in the hupA-hupB double deletion mutant. The mini-P1 plasmid was slightly unstable in the himA-hip mutant, whereas the mini-F plasmid was stable.     

Characterisation of new symbiotic Medicago truncatula (Gaertn.) mutants, and phenotypic or genotypic complementary information on previously described mutants

From a pool of Medicago truncatula mutants—obtained by gamma-irradiation or ethyl methanesulfonate mutagenesis—impaired in symbiosis with the N-fixing bacterium Sinorhizobium meliloti, new mutants are described and genetically analysed, and for already reported mutants, complementary data are given on their phenotypic and genetic analysis. Phenotypic data relate to nodulation and mycorrhizal phenotypes. Among the five new mutants, three were classified as [Nod⁺ Fix^– Myc⁺] and the mutations were ascribed to two loci, Mtsym20 (TRV43, TRV54) and Mtsym21 (TRV49). For the two other new mutants, one was classified as [Nod^–/+ Myc⁺] with a mutation ascribed to gene Mtsym15 (TRV48), and the other as [Nod^– Myc^-/+] with a mutation ascribed to gene Mtsym16 (TRV58). Genetic analysis of three previously described mutants has shown that [Nod^–/+ Myc⁺] TR74 mutant can be ascribed to gene Mtsym14, and that [Nod^–/+ Myc^–/+] TR89 and TRV9 mutants are ascribed to gene Mtsym2 (dmi2). Using a detailed analysis of mycorrhizal phenotype, we have observed a delayed typical arbuscular mycorrhizal formation on some mutants that present thick lens-shaped appressoria. This phenotype was called [Myc^–/+] and mutants TR25, TR26, TR89, TRV9, P1 and Y6 were reclassified as [Myc^–/+]. Mutant P1 was reclassified as [Nod^–/+] because of a late nodulation observed on roots of this mutant.     

Regulation of zebrafish primordial germ cell migration by attraction towards an intermediate target.

Migration of primordial germ cells (PGCs) from their site of specification towards the developing gonad is controlled by directional cues from somatic tissues. Although in several animals the PGCs are attracted by signals emanating from their final target, the gonadal mesoderm, little is known about the mechanisms that control earlier steps of migration. We provide evidence that a key step of zebrafish PGC migration, in which the PGCs become organized into bilateral clusters in the anterior trunk, is regulated by attraction of PGCs towards an intermediate target. Time-lapse observations of wild-type and mutant embryos reveal that bilateral clusters are formed at early somitogenesis, owing to migration of PGCs towards the clustering position from medial, posterior and anterior regions. Furthermore, PGCs migrate actively relative to their somatic neighbors and they do so as individual cells. Using mutants that exhibit defects in mesoderm development, we show that the ability to form PGC clusters depends on proper differentiation of the somatic cells present at the clustering position. Based on these findings, we propose that these somatic cells produce signals that attract PGCs. Interestingly, fate-mapping shows that these cells do not give rise to the somatic tissues of the gonad, but rather contribute to the formation of the pronephros. Thus, the putative PGC attraction center serves as an intermediate target for PGCs, which later actively migrate towards a more posterior position. This final step of PGC migration is defective in hands off mutants, where the intermediate mesoderm of the presumptive gonadal region is mispatterned. Our results indicate that zebrafish PGCs are guided by attraction towards two signaling centers, one of which may represent the somatic tissues of the gonad.     

Transposon-induced symbiotic mutants of Bradyrhizobium japonicum: isolation of two gene regions essential for nodulation

Summary Two strains of the soybean endosymbiont Bradyrhizobium japonicum, USDA 110 and 61 A101 C, were mutagenized with transposon Tn5. After plant infection tests of a total of 6,926 kanamycin and streptomycin resistant transconjugants, 25 mutants were identified that are defective in nodule formation (Nod^-) or nitrogen fixation (Fix^-). Seven Nod^- mutants were isolated from strain USDA 110 and from strain 61 A101 C, 4 Nod^- mutants and 14 Fix^- mutants were identified. Subsequent auxotrophic tests on these symbiotically defective mutants identified 4 His^- Nod^- mutants of USDA 110. Genomic Southern analysis of the 25 mutants revealed that each of them carried a single copy of Tn5 integrated in the genome. Three 61 A101 C Fix^- mutants were found to have vector DNA co-integrated along with Tn5 in the genome. Two independent DNA regions flanking Tn5 were cloned from the three nonauxotrophic Nod^- mutants and one His^-Nod^- mutant of USDA 110. Homogenotization of the cloned fragments into wild-type strain USDA 110 and subsequent nodulation assay of the resulting homogenotes confirmed that the Tn5 insertion was responsible for the Nod^- phenotype. Partial EcoR1 restriction enzyme maps around the Tn5 insertion sites were generated. Hybridization of these cloned regions to the previously cloned nod regions of R. meliloti and nif and nod regions of B. japonicum USDA 110 showed no homology, suggesting that these regions represent new symbiotic clusters of B. japonicum.