In vitro studies have suggested that connexin43 (cx43) expression is of particular importance during establishment and regeneration of the mammalian hematopoietic system. However, little is known about its in vivo functions during hematopoiesis due to the embryonic lethality of mammalian knockout models. In this study, we observed that zebrafish cx43 is not only expressed in the eyes, cerebellum, heart, and vasculature, but also expressed, albeit at low levels, in intermediate cell mass (ICM, the primitive hematopoietic site). Knockdown of cx43 leads to vacuolization in the wedge of the ICM and an apparent reduction in the number of circulating blood cells, but does not affect their cellular morphology. Whole-mount in situ hybridization analysis revealed that the hemangioblastic marker flk-1 and the primitive hematopoietic markers lmo2 and scl are basically maintained at normal levels in cx43 morphant embryos at 12-13 h postfertilization (hpf) compared with the con-MO injected embryos. However, subsequent expression of the definitive hematopoietic stem cell (HSC) marker c-myb was severely downregulated in the ventral wall of the dorsal aorta of cx43-depleted embryos at 36 hpf. Furthermore, we confirmed this phenotype by injection of cx43-MO into Tg(gata1:EGFP) embryos. Together, our results show that cx43 contributes to late primitive and definitive hematopoiesis in zebrafish embryos.

Childhood T-cell precursor acute lymphoblastic leukemia (TCP ALL) is an aggressive disease with a presumably short latency that differs in many biologic respects from B-cell precursor (BCP) ALL. We therefore addressed the issue of in utero origin of this particular type of leukemia by tracing oncogenic mutations and clone-specific molecular markers back to birth. These markers included various first- and second-hit genetic alterations (TCRD-LMO2 breakpoint regions, n = 2; TAL1 deletions, n = 3; Notch1 mutations, n = 1) and nononcogenic T-cell receptor rearrangements (n = 13) that were derived from leukemias of 16 children who were 1.5 to 11.2 years old at diagnosis of leukemia. Despite highly sensitive polymerase chain reaction (PCR) approaches (1 cell with a specific marker among 100,000 normal cells), we identified the leukemic clone in the neonatal blood spots in only 1 young child. These data suggest that in contrast to BCP ALL most TCP ALL cases are initiated after birth.

BACKGROUND

Clinical outcome in patients with primary central nervous lymphoma (PCNSL) is variable and poorly predictable. This study investigated the association of clinical features and immune markers with prognosis of patients with PCNSL.

METHODS

One hundred and fifteen newly diagnosed PCNSL patients at the study institution were considered eligible for this study. Clinical characteristics and biochemical assay data were collected. Immunohistochemical staining of Cyclin D3, Cyclin E, Foxp1, and LMO2 were performed. All cases were followed-up regularly.

RESULTS

The common sites of involvement were frontal lobe (54.8%) and thalamus (16.5%). Diffuse large B-cell lymphoma composed of 96.5% of the cases. The median overall survival was 22 (4 - 41) months, and the 5-year survival rate was 22.8%. Age>> 65 years, serum globulin>> 40 g/L, large size of tumor, lymphocyte count ≥ 1 × 10(9)/L, and expression of Cyclin D3 and Cyclin E were associated with poor prognosis of PCNSL. Expressions of Foxp1, LMO2, and CD44 were not related to the survival. Expression of Cyclin E, large tumor size, and high serum globulin were independent prognostic factors for PCNSL.

CONCLUSIONS

PCNSL prognosis is relatively poor. Age, high tumor burden, higher lymphocyte count, expression of Cyclin D3, and Cyclin E are inferior prognostic factors for PCNSL.

Diffuse large B-cell lymphoma (DLBCL) is classified into prognostically distinct germinal center B-cell (GCB) and activated B-cell subtypes by gene expression profiling (GEP). Recent reports suggest the role of GEP subtypes in targeted therapy. Immunohistochemistry (IHC) algorithms have been proposed as surrogates of GEP, but their utility remains controversial. Using microarray, we examined the concordance of 4 GEP-correlated and 2 non-GEP-correlated IHC algorithms in 381 DLBCLs, not otherwise specified. Subtypes and variants of DLBCL were excluded to minimize the possible confounding effect on prognosis and phenotype. Survival was analyzed in 138 cyclophosphamide, adriamycin, vincristine, and prednisone (CHOP)-treated and 147 rituximab plus CHOP (R-CHOP)-treated patients. Of the GEP-correlated algorithms, high concordance was observed among Hans, Choi, and Visco-Young algorithms (total concordance, 87.1%; κ score: 0.726 to 0.889), whereas Tally algorithm exhibited slightly lower concordance (total concordance 77.4%; κ score: 0.502 to 0.643). Two non-GEP-correlated algorithms (Muris and Nyman) exhibited poor concordance. Compared with the Western data, incidence of the non-GCB subtype was higher in all algorithms. Univariate analysis showed prognostic significance for Hans, Choi, and Visco-Young algorithms and BCL6, GCET1, LMO2, and BCL2 in CHOP-treated patients. On multivariate analysis, Hans algorithm retained its prognostic significance. By contrast, neither the algorithms nor individual antigens predicted survival in R-CHOP treatment. The high concordance among GEP-correlated algorithms suggests their usefulness as reliable discriminators of molecular subtype in DLBCL, not otherwise specified. Our study also indicates that prognostic significance of IHC algorithms may be limited in R-CHOP-treated Asian patients because of the predominance of the non-GCB type.

Primitive erythropoiesis follows a stereotypic developmental program of mesoderm ventralization and internalization, hemangioblast formation and migration, and erythroid lineage specification. Induction of erythropoiesis is inefficient in either ES/iPS cells in vitro or nonhemangioblast cell populations in vivo. Using the chick model, we report that epiblast cells can be directly and efficiently differentiated into the erythroid lineage by expressing five hematopoietic transcription regulators (SCL+LMO2+GATA2+LDB1+E2A) and inhibiting the FGF pathway. We show that these five genes are expressed with temporal specificity during normal erythropoiesis. Initiation of SCL and LMO2 expression requires FGF activity, whereas erythroid differentiation is enhanced by FGF inhibition. The lag between hematopoiesis and erythropoiesis is attributed to sequential coregulator expression and hemangioblast migration. Globin gene transcription can be ectopically and prematurely induced by manipulating the availability of these factors and the FGF pathway activity. We propose that similar approaches can be taken for efficient erythroid differentiation in vitro.

Erythropoietin is the principal regulator of erythropoiesis and promotes the survival, proliferation and differentiation of erythroid progenitor cells in mammals. In this study we report on the molecular and functional characterization of erythropoietin from the goldfish. Quantitative expression analysis of goldfish epo revealed the highest mRNA levels in heart, followed by brain, liver, spleen and kidney tissues. There was no marked change of epo expression in goldfish primary kidney macrophage cultures, as progenitor cell to macrophage development progressed, indicating that erythropoietin is not involved in monopoiesis. Recombinant goldfish erythropoietin induced proliferation of progenitor cells in a dose-dependent manner, and up-regulated the expression of erythroid transcription factors gata1 and lmo2 in progenitor cells. Furthermore, recombinant goldfish erythropoietin stimulated erythroid colony formation in a dose-dependent manner and promoted survival of erythroid progenitor cells as colony-forming cells. Our results demonstrate that the function of erythropoietin in the goldfish is similar to that of mammals and suggest a highly conserved mechanism of early erythrocyte development in lower and higher vertebrates.

Hematopoietic stem progenitor cells (HSPCs) are highly enriched in a rare subset of Lin-CD34+CD38- cells. Independent of stage of human development, HSPC function segregates to the subset of Lin-CD34+CD38- cells. However, fetal-derived HSPCs demonstrate distinct self-renewal and differentiation capacities compared with their adult counterparts. Here, to characterize the molecular nature of fetal HSPCs, suppressive subtractive hybridization was used to compare gene expression of HSPCs isolated from fetal blood (FB-HSPCs) versus adult mobilized peripheral blood (MPB-HSPCs). We identified 97 differentially expressed genes that could be annotated into distinct groups that include transcription factors, cell cycle regulators, and genes involved in signal transduction. Candidate regulators, such as Lim only domain-2 (LMO2), nuclear factor-kappa B (NF-kappaB), tripartite motif 28 (Trim28), and N-myc protooncogene (MYCN), and a novel homeobox gene product were among transcripts that were found to be differentially expressed and could be associated with specific proliferation and differentiation properties unique to FB-HSPCs. Interestingly, the majority of genes associated with signal transduction belong to Ras pathway, highlighting the significance of Ras signaling in FB-HSPCs. Genes differentially expressed in FB-HSPCs versus adult MPB-HSPCs were verified using quantitative real-time polymerase chain reaction (Q-PCR). This approach also resulted in the identification of a transcript that is highly expressed in FB-HSPCs but not detectable in more differentiated Lin-CD34+CD38+ FB progenitors. Our investigation represents the first study to compare phenotypically similar, but functionally distinct, HSPC populations and to provide a gene profile of unique human HSPCs with higher proliferative capacity derived from early in utero human blood development.

In this study, we present a remarkable clonal cell line, 32080, derived from a CD2-Lmo2- transgenic T-cell leukemia with differentiation arrest at the transition from the intermediate single positive to double positive stages of T-cell development. We observed that 32080 cells had a striking variegated pattern in CD4 expression. There was cell-to-cell variability, with some cells expressing no CD4 and others expressing high CD4. The two populations were isogenic and yet differed in their rates of apoptosis and sensitivity to glucocorticoid. We sorted the 32080 line for CD4-positive or CD4-negative cells and observed them in culture. After 1 week, both sorted populations showed variegated CD4 expression, like the parental line, showing that the two populations could interconvert. We determined that cell replication was necessary to transit from CD4(+) to CD4(-) and CD4(-) to CD4(+). Lmo2 knockdown decreased CD4 expression, while inhibition of intracellular NOTCH1 or histone deacetylase activity induced CD4 expression. Enforced expression of RUNX1 repressed CD4 expression. We analyzed the CD4 locus by Histone 3 chromatin immunoprecipitation and found silencing marks in the CD4(-) cells and activating marks in the CD4(+) population. The 32080 cell line is a striking model of intermediate single positive to double positive T-cell plasticity and invokes a novel mechanism for LMO2's oncogenic functions.

Lmo2 is a T cell leukemia-related proto-oncogene, which belongs to the LIM protein family. Previous work has established its key role in yolk sac erythropoiesis and adult hematopoiesis, and it is also necessary for regulating angiogenesis. It has been demonstrated that this gene encodes a protein of 158 amino acids, consisting of two tandem cysteine-rich LIM domains, but the detailed mechanism of its transcriptional regulation remains to be elucidated. To further investigate the mechanism of transcriptional regulation of Lmo2, we combined SMART PCR technology with 5'RACE and found a novel post-transcriptional splicing form of Lmo2 in adult human kidney. This alternative transcript contains only two exons, encoding a smaller protein of 151 amino acids. Interestingly, it shares the same reading frame as the original Lmo2, but differs in 7 amino acids at the N-terminus. A genomic DNA fragment (from -294 nts to +180 nts) containing the putative promoter region has been inserted into the luciferase reporter gene vector pGL3-basic and showed stable promoter activity when transfected into COS7. RT-PCR analysis revealed that this variant transcript was expressed widely in human tissues and cell lines, suggesting its potential basic functional importance.

The gene encoding LIM-only 2 (LMO2), an oncogenic transcription factor, is frequently activated in T cell acute lymphoblastic leukemia (T-ALL), but how LMO2 transforms primary hematopoietic cells to induce T-ALL remains an open question. McCormack et al. now show that, in mice, Lmo2 confers self-renewal potential on normally nonrenewing thymocyte progenitor cells, and this property is maintained over four serial transplantations when the cells are transplanted into irradiated mice that lack thymocytes. These leukemia-initiating cells are resistant to irradiation, indicating the need to develop new therapeutic drugs that specifically target the oncogene itself.

Stathmin (STMN1) is a microtubule destabilizing protein with a key role in cell cycle progression and cell migration that is up-regulated in several cancers and may contribute to the malignant phenotype. However, the factors that regulate its expression are not well understood. Loss as well as gain-of-function p53 mutations up-regulate STMN1 and in acute myelogenous leukemia where p53 is predominantly wild-type, STMN1 is also over-expressed. Here we show regulatory control of STMN1 expression by the leucine zipper transcription factor (TF) CREB1 and the basic helix-loop-helix TF LYL1. By ChIP-chip experiments we demonstrate in vivo the presence of LYL1 and CREB1 in close proximity on the STMN1 promoter and using promoter assays we reveal co-regulation of STMN1 by CREB1 and LYL1. By contrast, TAL1, another suspected oncoprotein in leukemia and close relative of LYL1, exerts no regulatory effect on the STMN1 promoter. NLI, LMO2 and GATA2 are previously described co-activators of Tal1/Lyl1-E47 transcriptional complexes and potentiate Lyl1 activation of the STMN1 promoter while having no effect on TAL1 transactivation. Promoter mutations that abrogate CREB1 proximal binding or mutations of the DNA-binding domain of CREB1 abolish LYL1 transcriptional activation. These results show that CRE and Ebox sites function as coordinated units and support previous evidence of joint CREB1-and LYL1 transcription events activating an aberrant subset of promoters in leukemia. CREB1 or LYL1 shRNA knock-down down-regulate STMN1 expression. Because down-regulation of STMN1 has been shown to have anti-proliferative effects, while CREB1 and LYL1 are suspected oncoproteins, interference with CREB1-LYL1 interactions may complement standard chemotherapy and yield additional beneficial effects.

OBJECTIVE

Loss of IKAROS in committed B cell precursors causes a block in differentiation while at the same time augments aberrant cellular properties, such as bone marrow stromal adhesion, self-renewal and resistance to glucocorticoid-mediated cell death. B cell acute lymphoblastic leukaemias originating from these early stages of B cell differentiation and associated with IKAROS mutations share a high-risk cellular phenotype suggesting that deregulation of IKAROS-based mechanisms cause a highly malignant disease process.

UNASSIGNED

Recent studies show that IKAROS is critical for the activity of super-enhancers at genes required for pre-B cell receptor (BCR) signalling and differentiation, working either downstream of or in parallel with B cell master regulators such as EBF1 and PAX5. IKAROS also directly represses a cryptic regulatory network of transcription factors prevalent in mesenchymal and epithelial precursors that includes YAP1, TEAD1/2, LHX2 and LMO2, and their targets, which are not normally expressed in lymphocytes. IKAROS prevents not only expression of these 'extra-lineage' transcription factors but also their cooperation with endogenous B cell master regulators, such as EBF1 and PAX5, leading to the formation of a de novo for lymphocytes super-enhancer network. IKAROS coordinates with the Polycomb repression complex (PRC2) to provide stable repression of associated genes during B cell development. However, induction of regulatory factors normally repressed by IKAROS starts a feed-forward loop that activates de-novo enhancers and elevates them to super-enhancer status, thereby diminishing PRC2 repression and awakening aberrant epithelial-like cell properties in B cell precursors.

CONCLUSIONS

Insight into IKAROS-based transcriptional circuits not only sets new paradigms for cell differentiation but also provides new approaches for classifying and treating high-risk human B-ALL that originates from these early stages of B cell differentiation.

Mice lacking the 4th-group paralog Hoxd4 display malformations of the anterior vertebral column, but are viable and fertile. Here, we report that zebrafish embryos having decreased function of the orthologous hoxd4a gene manifest striking perturbations in vasculogenesis, angiogenesis and primitive and definitive hematopoiesis. These defects are preceded by reduced expression of the hemangioblast markers scl1, lmo2 and fli1 within the posterior lateral plate mesoderm (PLM) at 13 hours post fertilization (hpf). Epistasis analysis revealed that hoxd4a acts upstream of meis1.1 but downstream of cdx4 as early as the shield stage in ventral-most mesoderm fated to give rise to hemangioblasts, leading us to propose that loss of hoxd4a function disrupts hemangioblast specification. These findings place hoxd4a high in a genetic hierarchy directing hemangioblast formation downstream of cdx1/cdx4 and upstream of meis1.1. An additional consequence of impaired hoxd4a and meis1.1 expression is the deregulation of multiple Hox genes implicated in vasculogenesis and hematopoiesis which may further contribute to the defects described here. Our results add to evidence implicating key roles for Hox genes in their initial phase of expression early in gastrulation.

Long noncoding RNAs (lncRNAs) are being discovered in multiple diseases at a rapid pace. However, the contribution of lncRNAs to hypertension remains largely unknown. In hypertension, the vascular walls are exposed to abnormal mechanical cyclic strain, which leads to vascular remodelling. Here, we investigated the mechanobiological role of lncRNAs in hypertension.

Differences in the lncRNAs and mRNAs between spontaneously hypertensive rats and Wistar-Kyoto rats were screened using a gene microarray. The results showed that 68 lncRNAs and 255 mRNAs were upregulated in the aorta of spontaneously hypertensive rats, whereas 167 lncRNAs and 272 mRNAs were downregulated. Expressions of the screened lncRNAs, including XR007793, were validated by real-time PCR. A coexpression network was composed, and gene function was analysed using Ingenuity Pathway Analysis. In vitro, vascular smooth muscle cells (VSMCs) were subjected to cyclic strain at a magnitude of 5 (physiological normotensive cyclic strain) or 15% (pathological hypertensive cyclic strain) by Flexcell-4000T. A total of 15% cyclic strain increased XR007793 expression. XR007793 knockdown attenuated VSMC proliferation and migration and inhibited coexpressed genes such as signal transducers and activators of transcription 2 (stat2), LIM domain only 2 (lmo2) and interferon regulatory factor 7 (irf7).

The profile of lncRNAs was varied in response to hypertension, and pathological elevated cyclic strain may play crucial roles during this process. Our data revealed a novel mechanoresponsive lncRNA-XR007793, which modulates VSMC proliferation and migration, and participates in vascular remodelling during hypertension.

The LMO2 gene is involved in T-cell acute leukaemia (T-ALL) in children with chromosomal translocations t(11;14)(p13;q11) or (7;11)(q35;p13). Transgenic expression of Lmo2 in T cells results in clonal tumours with long latency indicating that mutations in other genes are required for the development of overt tumours. RAG V-D-J recombinase can mediate genetic transposition and thus might create the secondary mutations necessary for T-ALL. Tumour development was compared in Lmo2 transgenic mice in the presence or absence of the Rag1 gene. No difference was observed in the rate of tumour formation nor in tumour histology in Lmo2-transgenic mice with or without Rag1. We conclude that, in this model, RAG recombinase is not a major mediator of mutations needed for T cell tumorigenesis and that antigen binding to alpha-beta or to gamma-delta T cell receptor does not play a role in tumorigenesis. The driving force behind the mutational process involved in this transgenic model remains obscure.

NOD mice exhibit major defects in the earliest stages of T cell development in the thymus. Genome-wide genetic and transcriptome analyses were used to investigate the origins and consequences of an early T cell developmental checkpoint breakthrough in Rag1-deficient NOD mice. Quantitative trait locus analysis mapped the presence of checkpoint breakthrough cells to several known NOD diabetes susceptibility regions, particularly insulin-dependent diabetes susceptibility genes (Idd)9/11 on chromosome 4, suggesting common genetic origins for T cell defects affecting this trait and autoimmunity. Genome-wide RNA deep-sequencing of NOD and B6 Rag1-deficient thymocytes revealed the effects of genetic background prior to breakthrough, as well as the cellular consequences of the breakthrough. Transcriptome comparison between the two strains showed enrichment in differentially expressed signal transduction genes, prominently tyrosine kinase and actin-binding genes, in accord with their divergent sensitivities to activating signals. Emerging NOD breakthrough cells aberrantly expressed both stem cell-associated proto-oncogenes, such as Lmo2, Hhex, Lyl1, and Kit, which are normally repressed at the commitment checkpoint, and post-β-selection checkpoint genes, including Cd2 and Cd5. Coexpression of genes characteristic of multipotent progenitors and more mature T cells persists in the expanding population of thymocytes and in the thymic leukemias that emerge with age in these mice. These results show that Rag1-deficient NOD thymocytes have T cell defects that can collapse regulatory boundaries at two early T cell checkpoints, which may predispose them to both leukemia and autoimmunity.

LIM domain only-2 (LMO2) is an important regulator of hematopoietic stem cell development. LMO2 protein is expressed in all three hematopoietic lineages precursors of the hematopoietic system, and its expression has been shown to decrease gradually during differentiation. Chronic myeloid leukemia (CML) is a malignant clonal myeloproliferative disorder in which the terminal differentiation is not altered until the appearance of an accelerated or blast phase. We examined whether LMO2 protein expression can predict outcome CML patients undergoing tyrosine kinase inhibitor therapy, imatinib mesylate (IM). Immunohistochemistry on bone marrow biopsy material for LMO2 protein was performed in 47 CML patients. We report that the LMO2 protein expression is correlated with improved hematologic remission and overall survival in the CML patients treated with IM. The immunohistologic analysis of LMO2 protein expression may become a predictive factor for anticipating the treatment responses of CML patients.

Listeria (L.) monocytogenes, a foodborne pathogen, is known to be a possible contaminant of foods during production and processing. Samples (n=985) of raw meat and by-products obtained from beef and pork were first screened by the VIDAS system for the presence of Listeria spp., followed by testing for the presence of L. monocytogenes. Positive L. monocytogenes results were confirmed by plating on selective agars: 14% of the samples were positive for Listeria and 4% tested positive for L. monocytogenes, of which 3% were confirmed on selective agars. In by-products (17%) the contamination with listeriae was higher than in meat cuts (10%). Only samples strongly positive for Listeria spp. by VIDAS were positive for L. monocytogenes. Overall, the prevalence of L. monocytogenes in beef and pork samples was rather low in comparison to most previous studies. The VIDAS system was shown to be a suitable method for screening out Listeria-negative samples; the main advantage being a markedly reduced assay time.

Retroviral gene therapy has proved efficacious for multiple genetic diseases of the hematopoietic system, but roughly half of clinical gene therapy trial protocols using gammaretroviral vectors have reported leukemias in some of the patients treated. In dramatic contrast, 39 adenosine deaminase-deficient severe combined immunodeficiency (ADA-SCID) patients have been treated with 4 distinct gammaretroviral vectors without oncogenic consequence. We investigated clonal dynamics and diversity in a cohort of 15 ADA-SCID children treated with gammaretroviral vectors and found clear evidence of genotoxicity, indicated by numerous common integration sites near proto-oncogenes and by increased abundance of clones with integrations near MECOM and LMO2 These clones showed stable behavior over multiple years and never expanded to the point of dominance or dysplasia. One patient developed a benign clonal dominance that could not be attributed to insertional mutagenesis and instead likely resulted from expansion of a transduced natural killer clone in response to chronic Epstein-Barr virus viremia. Clonal diversity and T-cell repertoire, measured by vector integration site sequencing and T-cell receptor β-chain rearrangement sequencing, correlated significantly with the amount of busulfan preconditioning delivered to patients and to CD34+ cell dose. These data, in combination with results of other ADA-SCID gene therapy trials, suggest that disease background may be a crucial factor in leukemogenic potential of retroviral gene therapy and underscore the importance of cytoreductive conditioning in this type of gene therapy approach.

The first intronic mutations in the intron 1 GATA site (int-1-GATA) of 5-aminolevulinate synthase 2 (ALAS2) have been identified in X-linked sideroblastic anemia (XLSA) pedigrees, strongly suggesting it could be causal mutations of XLSA. However, the function of this int-1-GATA site during in vivo development remains largely unknown. Here, we generated mice lacking a 13 bp fragment, including this int-1-GATA site (T AGATAA: AGCCCC) and found that hemizygous deletion led to an embryonic lethal phenotype due to severe anemia resulting from a lack of ALAS2 expression, indicating that this non-coding sequence is indispensable for ALAS2 expression in vivo Further analyses revealed that this int-1-GATA site anchored the GATA site in intron 8 (int-8-GATA) and the proximal promoter, forming a long-range loop to enhance ALAS2 expression by an enhancer complex including GATA1, TAL1, LMO2, LDB1 and Pol II at least, in erythroid cells. However, compared with the int-8-GATA site, the int-1-GATA site is more essential for regulating ALAS2 expression through CRISPR/Cas9-mediated site-specific deletion. Therefore, the int-1-GATA site could serve as a valuable site for diagnosing XLSA in cases with unknown mutations.

Thyroid cancer patients frequently have favorable outcomes. However, a small subset develops aggressive disease refractory to traditional treatments. Therefore, we sought to characterize oncogenic mutations in thyroid cancers to identify novel therapeutic targets that may benefit patients with advanced, refractory disease.

Data on 239 thyroid cancer specimens collected between January 2009 and September 2014 were obtained from the Dana Farber/Brigham and Women's Cancer Center. The tumors were analyzed with the OncoMap-4 or OncoPanel high-throughput genotyping platforms that survey up to 275 cancer genes and 91 introns for DNA rearrangement.

Of the 239 thyroid cancer specimens, 128 (54%) had oncogenic mutations detected. These 128 tumors had 351 different mutations detected in 129 oncogenes or tumor suppressors. Examination of the 128 specimens demonstrated that 55% (n = 70) had 1 oncogenic mutation, and 45% (n = 48) had more than 1 mutation. The 351 oncogenic mutations were in papillary (85%), follicular (4%), medullary (7%), and anaplastic (4%) thyroid cancers. Analysis revealed that 2.3% (n = 3 genes) of the somatic gene mutations were novel. These included AR (n = 1), MPL (n = 2), and EXT2 (n = 1), which were present in 4 different papillary thyroid cancer specimens. New mutations were found in an additional 13 genes known to have altered protein expression in thyroid cancer: BLM, CBL, CIITA, EP300, GSTM5, LMO2, PRAME, SBDS, SF1, TET2, TNFAIP3, XPO1, and ZRSR2.

This analysis revealed that several previously unreported oncogenic gene mutations exist in thyroid cancers and may be targets for the development of future therapies. Further investigation into the role of these genes is warranted.

Serum response factor (SRF), a transcription factor known to be essential for early embryonic development as well as post-natal regulation of both cellular proliferation and myogenic differentiation, is expressed broadly in neurons within the adult mammalian central nervous system (CNS). The function of SRF within the developing CNS is not well established, but it is likely to play an important role in neuraxial development and neuronal function, since many of its known target genes (e.g., c-fos) and transcriptional partners (e.g., Elk-1) are also highly expressed in neurons. Immunohistochemical survey of the post-natal developing rat brain revealed a progressive increase in SRF immunoreactivity in neurons of the cerebral and cerebellar cortices, and in selective subcortical regions from birth (P0) through post-natal day 28 (P28). SRF immunoreactivity stabilized from P28 into adulthood. A few loci, such as the nucleus of cranial nerve VII, showed the reverse expression pattern (strong immunoreactivity at P0-P7, declining by P28). The developmental expression pattern of SRF overlaps significantly with that of myotonic dystrophy protein kinase, a potential upstream regulator, and of the LIM-only genes Lmo1, Lmo2 and Lmo3, whose products belong to a family of proteins known to be strong positive regulators of SRF's transcriptional activity. These data suggest that SRF has a significant function in the early post-natal development of the CNS.