Negative feedback by NUR77/Nr4a1 restrains B cell clonal dominance during early T-dependent immune responses.

B cell clones compete for entry into and dominance within germinal centers (GCs), where the highest-affinity B cell receptors (BCRs) are selected. However, diverse and low-affinity B cells can enter and reside in GCs for extended periods. To reconcile these observations, we hypothesize that a negative feedback loop may operate within B cells to preferentially restrain high-affinity clones from monopolizing the early GC niche. Here, we report a role for the nuclear receptor NUR77/Nr4a1 in this process. We show that NUR77 expression scales with antigen stimulation and restrains B cell expansion. Although NUR77 is dispensable for regulating GC size when GCs are elicited in a largely clonal manner, it serves to curb immunodominance under conditions where diverse clonal populations must compete for a constrained niche. We propose that this is important to preserve early clonal diversity in order to limit holes in the post-immune repertoire and to optimize GC selection.

NR4A nuclear receptors restrain B cell responses to antigen when second signals are absent or limiting.

Antigen stimulation (signal 1) triggers B cell proliferation and primes B cells to recruit, engage and respond to T cell help (signal 2). Failure to receive signal 2 within a defined time window results in B cell apoptosis, yet the mechanisms that enforce dependence on co-stimulation are incompletely understood. Nr4a1-3 encode a small family of orphan nuclear receptors that are rapidly induced by B cell antigen receptor stimulation. Here, we show that Nr4a1 and Nr4a3 play partially redundant roles to restrain B cell responses to antigen in the absence of co-stimulation and do so, in part, by repressing the expression of BATF and, consequently, MYC. The NR4A family also restrains B cell access to T cell help by repressing expression of the T cell chemokines CCL3 and CCL4, as well as CD86 and ICAM1. Such NR4A-mediated regulation plays a role specifically under conditions of competition for limiting T cell help.

Eda/Edar signaling guides fin ray formation with preceding osteoblast differentiation, as revealed by analyses of the medaka all-fin less mutant afl.

BACKGROUND: Ectodysplasin (Eda) signaling is essential for the morphogenesis of several ectodermal appendages. RESULTS: Here, we report a medaka mutant, all-fin less (afl), which has a nonsense mutation in its eda gene. The adult afl fish displayed various abnormalities of its dermal skeleton, such as short and twisted fin rays, missing and abnormally shaped scales and teeth, and skull deformation. Focusing on the developing fin rays in the caudal region of afl larvae, we found that the fin rays did not elongate; although the initial formation of fin rays proceeded normally. Additionally, eda expression was lost, and the expression pattern of edar, the gene for the receptor of Eda, was different from wild-type one. In vivo imaging of the double-transgenic medaka expressing enhanced green fluorescent protein under control of the edar promoter and DsRed under control of the osterix promoter revealed that edar expression preceded that of osterix and that the edar-expressing cells migrated in the direction of fin ray elongation, indicating that the Eda/Edar signaling event precedes osteoblast differentiation. CONCLUSIONS: Our findings provide evidence that Eda signaling accompanied with the binding of Eda to Edar are essential for fin ray formation guided by cell migration.

Brpf1, a subunit of the MOZ histone acetyl transferase complex, maintains expression of anterior and posterior Hox genes for proper patterning of craniofacial and caudal skeletons.

The epigenetic mechanism involving chromatin modification plays a critical role in the maintenance of the expression of Hox genes. Here, we characterize a mutant of the medaka fish, named biaxial symmetries (bis), in which brpf1, a subunit of the MOZ histone acetyl transferase (HAT) complex, is mutated. The bis mutant displayed patterning defects both in the anterior-posterior axis of the craniofacial skeleton and the dorsal-ventral axis of the caudal one. In the anterior region, the bis mutant exhibited craniofacial cartilage homeosis. The expression of Hox genes was decreased in the pharyngeal arches, suggesting that the pharyngeal segmental identities were altered in the bis mutant. In the posterior region, the bis mutant exhibited abnormal patterning of the caudal skeleton, which ectopically formed at the dorsal side of the caudal fin. The expression of Zic genes was decreased at the posterior region, suggesting that the dorsal-ventral axis formation of the posterior trunk was disrupted in the bis mutant. We also found that the MOZ-deficient mice exhibited an abnormal patterning of their craniofacial and cervical skeletons and a decrease of Hox transcripts. We propose a common role of the MOZ HAT complex in vertebrates, a complex which is required for the proper patterning for skeletal development.

Mutation in the abcb7 gene causes abnormal iron and fatty acid metabolism in developing medaka fish.

The medaka fish (Oryzias latipes) is an emerging model organism for which a variety of unique developmental mutants have now been generated. Our recent mutagenesis screening of the medaka isolated a unique mutant that develops a fatty liver at larval stages. Positional cloning identified the responsible gene as medaka abcb7. Abcb7, a mitochondrial ABC (ATP binding cassette) half-transporter, has been implicated in iron metabolism. Recently, human Abcb7 was found to be mutated in X-linked sideroblastic anemia with cerebellar ataxia (XLSA/A). The homozygous medaka mutant exhibits abnormal iron metabolism in erythrocytes and accumulation of lipid in the liver. Microarray and in situ hybridization analyses demonstrated that the expression of genes involved in iron and lipid metabolisms are both affected in the mutant liver, suggesting novel roles of Abcb7 in the development of physiologically functional liver. The medaka abcb7 mutant thus could provide insights into the pathogenesis of XLSA/A as well as the normal function of the gene.

Characterization of mutations affecting embryonic hematopoiesis in the medaka, Oryzias latipes.

In a genetic screen for mutations affecting organogenesis in the medaka, Oryzias latipes, we identified eight mutants with defects in embryonic hematopoiesis. These mutations were classified into seven complementation groups. In this paper, we characterize the five mutants that were confirmed in the next generation. The beni fuji mutant was defective in the generation of blood cells, exhibiting reduced blood cells at the initiation of circulation. Mutations in two genes, lady finger and ryogyoku, caused abnormal morphology of blood cells, i.e., deformation, along with a progressive decrease in the number of blood cells. The sekirei mutant exhibited photosensitivity with autofluorescent blood cells. Mutations in kyoho resulted in huge blood cells that were approximately three times longer than the wild-type blood cells. The spectrum of phenotypes identified in this study is similar to that of the zebrafish hematopoietic mutants except for the huge blood cells in kyoho. Our results demonstrate that medaka, as well as zebrafish, is a useful model to study hematopoiesis.