Craig A. MacArthur

Roles for FGF8 in the Induction, Initiation, and Maintenance of Chick Limb Development

We provide evidence that FGF8 serves as an endogenous inducer of chick limb formation and that its expression in the intermediate mesoderm at the appropriate time and place to trigger forelimb development is directly linked to the mechanism of embryonic kidney differentiation. One function of the limb inducer is to initiate Fgf8 gene expression in the ectoderm overlying the prospective limb-forming territories. FGF8 secreted by the ectoderm then appears to initiate limb bud formation by promoting outgrowth of and Sonic hedgehog expression in the underlying lateral plate mesoderm. FGF8 also maintains mesoderm outgrowth and Sonic hedgehog expression in the established limb bud. Our data thus point to FGF8 as a key regulator of limb development that not only induces and initiates the formation of a limb bud, but also sustains its subsequent development.

Fgf-8 expression in the post-gastrulation mouse suggests roles in the development of the face, limbs and central nervous system

Fgf-8 is a member of the fibroblast growth factor (FGF) family that was initially identified as an androgen-inducible growth factor in a mammary carcinoma cell line. Alternative splicing of the primary Fgf-8 transcript results in three messenger RNAs which code for secreted FGF-8 protein isoforms that differ only in their mature amino termini. Fgf-8 RNA is present from day 10 through 12 of murine gestation when analyzed by northern blot analysis, suggesting that Fgf-8 normally functions during post-gastrulation development. To characterize the temporal, spatial and isoform-specific aspects of Fgf-8 expression during mouse development, we performed in situ hybridization and ribonuclease protection assays between the days 8 and 16 of gestation. Fgf-8 expression is first detected at day 9 of gestation in the surface ectoderm of the first branchial arches, the frontonasal process, the forebrain and the midbrain-hindbrain junction. At days 10-12 of gestation, Fgf-8 expression is detected in the surface ectoderm of the forelimb and hindlimb buds, in the nasal pits and nasopharynx, in the infundibulum and in the telencephalon, diencephalon and metencephalon. Fgf-8 expression continues in the developing hindlimbs through day 13 of gestation but is undetectable thereafter. Ribonuclease protection assays reveal that RNAs coding for all three FGF-8 isoforms are present at days 10-12 of gestation. These results reveal a unique temporal and spatial pattern of Fgf-8 expression in the developing mouse and suggest a role for this FGF in multiple regions of ectodermal differentiation in the post-gastrulation mouse embryo.

Overlapping Expression and Redundant Activation of Mesenchymal Fibroblast Growth Factor (FGF) Receptors by Alternatively Spliced FGF-8 Ligands

FGF-8 is a member of the family of fibroblast growth factors and is expressed during vertebrate embryo development. Eight potential FGF-8 isoforms are generated by alternative splicing in mice, several of which are expressed during embryogenesis in epithelial locations. The significance of the multiple isoforms is currently unknown. In this report, we investigate the expression patterns and the specificity of the FGF-8 isoforms for known fibroblast growth factor (FGF) receptors. RNAs for seven of the eight potential isoforms are present at multiple sites of embryonic Fgf8 expression. None of the FGF-8 isoforms exhibited activity when assayed with BaF3 cells expressing the “b” splice forms of FGF receptors 1-3, which are mostly expressed in epithelial tissues. Mesenchymally expressed “c” splice forms of FGF receptors 2 and 3 and FGF receptor 4 were activated by several FGF-8 isoforms. These findings are consistent with the hypothesis that the multiple FGF-8 isoforms are functionally redundant and function to signal in paracrine (epithelial to mesenchymal) contexts.

T γ/δ hepatosplenic lymphoma in a heart transplant patient after an Epstein-Barr virus positive lymphoproliferative disorder : A case report

An unusual case of a peripheral T‐cell lymphoma of T γ/δ hepatosplenic type (Tγ/δHSL) that arose in a child 5 years after she received a heart transplant and 9 months after she developed Epstein‐Barr virus (EBV) positive, B‐cell lymphoid hyperplasia involving the tonsils is presented. The majority of the reported cases of Tγ/δHSL have been described in young adult men without antecedent immunodeficiency; several well documented cases of Tγ/δHSL in the posttransplant setting have been described previously, but none has been described in a child (or an adult) with a previously diagnosed EBV+ B‐cell lymphoid hyperplasia.

Cloning, expression and nuclear localization of human NPM3, a member of the nucleophosmin/nucleoplasmin family of nuclear chaperones

BackgroundStudies suggest that the related proteins nucleoplasmin and nucleophosmin (also called B23, NO38 or numatrin) are nuclear chaperones that mediate the assembly of nucleosomes and ribosomes, respectively, and that these activities are accomplished through the binding of basic proteins via their acidic domains. Recently discovered and less well characterized members of this family of acidic phosphoproteins include mouse nucleophosmin/nucleoplasmin 3 (Npm3) and Xenopus NO29. Here we report the cloning and initial characterization of the human ortholog of Npm3.ResultsHuman genomic and cDNA clones of NPM3 were isolated and sequenced. NPM3 lies 5.5 kb upstream of FGF8 and thus maps to chromosome 10q24-26. In addition to amino acid similarities, NPM3 shares many physical characteristics with the nucleophosmin/nucleoplasmin family, including an acidic domain, multiple potential phosphorylation sites and a putative nuclear localization signal. Comparative analyses of 14 members of this family from various metazoans suggest that Xenopus NO29 is a candidate ortholog of human and mouse NPM3, and they further group both proteins closer with the nucleoplasmins than with the nucleophosmins. Northern blot analysis revealed that NPM3 was strongly expressed in all 16 human tissues examined, with especially robust expression in pancreas and testis; lung displayed the lowest level of expression. An analysis of subcellular fractions of NIH3T3 cells expressing epitope-tagged NPM3 revealed that NPM3 protein was localized solely in the nucleus.ConclusionsHuman NPM3 is an abundant and widely expressed protein with primarily nuclear localization. These biological activities, together with its physical relationship to the chaparones nucleoplasmin and nucleophosmin, are consistent with the proposed function of NPM3 as a molecular chaperone functioning in the nucleus.

Pathogenesis of ectrodactyly in the Dactylaplasia mouse: Aberrant cell death of the apical ectodermal ridge†

Dactylaplasia, or Dac, was recently mapped to the distal portion of mouse chromosome 19 and shown to be inherited as an autosomal semi-dominant trait characterized by missing central digital rays. The most common locus for human split hand split foot malformation, also typically characterized by missing central digital rays, is 10q25, a region of synteny to the Dac locus. The Dac mouse appears to be an ideal genotypic and phenotypic model for this human malformation syndrome. Several genes lie in this region of synteny, however, only Fibroblast Growth Factor 8, or Fgf-8, has been implicated to have a role in limb development. We demonstrate that the developmental mechanism underlying loss of central rays in Dac limbs is dramatic cell death of the apical ectodermal ridge, or AER. This cell death pattern is apparent in E10.5-11.5 Dac limb buds stained with the supravital dye Nile Blue Sulfate. We demonstrate that Fgf8 expression in wild type limbs colocalizes spatially and temporally with AER cell death in Dac limbs. Furthermore, in our mapping panel, there is an absence of recombinants between Fgf-8 and the Dac locus in 133 backcross progeny with a median linkage estimate of approximately 0.5 cM. Thus, our results demonstrate that cell death of the AER in Dac limbs silences the role of the AER as key regulator of limb outgrowth, and that Fgf-8 is a strong candidate for the cause of the Dac phenotype.

The importance of Phase I/II trials in pediatric oncology

SummaryClinical trials in pediatric oncology over the past 30 years have led to the situation today where most children with newly diagnosed cancer can be treated effectively, and many are cured. Despite this dramatic improvement in outcome for many children diagnosed with cancer, about 30–40% of children will die of their disease [1]. Although some attempts have been made to improve outcome by increasing the dose intensity of existing therapies, intolerable side effects and marginal increases in cancer cell kill limit this approach. Clearly, effective new anti-cancer agents are necessary to significantly improve the survival and quality of life in children with cancer. Well-organized pediatric Phase I trials to establish the maximum tolerated dose (MTD), and Phase II trials to establish efficacy, are critical to the identification of new anti-cancer agents.