In vivo analysis of <Emphasis Type="Italic">Drosophila</Emphasis> SU(<Emphasis Type="Italic">Z</Emphasis>)12 function

Polycomb group (PcG) proteins are required to maintain a stable repression of the homeotic genes during Drosophila development. Mutants in the PcG gene Supressor of zeste 12 (Su(z)12) exhibit strong homeotic transformations caused by widespread misexpression of several homeotic genes in embryos and larvae. Su(z)12 has also been suggested to be involved in position effect variegation and in regulation of the white gene expression in combination with zeste. To elucidate whether SU(Z)12 has any such direct functions we investigated the binding pattern to polytene chromosomes and compared the localization to other proteins. We found that SU(Z)12 binds to about 90 specific eukaryotic sites, however, not the white locus. We also find staining at the chromocenter and the nucleolus. The binding along chromosome arms is mostly in interbands and these sites correlate precisely with those of Enhancer-of-zeste and other components of the PRC2 silencing complex. This implies that SU(Z)12 mainly exists in complex with PRC2. Comparisons with other PcG protein-binding patterns reveal extensive overlap. However, SU(Z)12 binding sites and histone 3 trimethylated lysine 27 residues (3meK27 H3) do not correlate that well. Still, we show that Su(z)12 is essential for tri-methylation of the lysine 27 residue of histone H3 in vivo, and that overexpression of SU(Z)12 in somatic clones results in higher levels of histone methylation, indicating that SU(Z)12 is rate limiting for the enzymatic activity of PRC2. In addition, we analyzed the binding pattern of Heterochromatin Protein 1 (HP1) and found that SU(Z)12 and HP1 do not co-localize.     

Central role of Drosophila SU(VAR)3-9 in histone H3-K9 methylation and heterochromatic gene silencing

Su(var)3-9 is a dominant modifier of heterochromatin-induced gene silencing. Like its mammalian and Schizosaccharomyces pombe homologues, Su(var) 3-9 encodes a histone methyltransferase (HMTase), which selectively methylates histone H3 at lysine 9 (H3-K9). In Su(var)3-9 null mutants, H3-K9 methylation at chromocentre heterochromatin is strongly reduced, indicating that SU(VAR)3-9 is the major heterochromatin-specific HMTase in Drosophila. SU (VAR)3-9 interacts with the heterochromatin-associated HP1 protein and with another silencing factor, SU(VAR)3-7. Notably, SU(VAR)3-9-HP1 interaction is interdependent and governs distinct localization patterns of both proteins. In Su(var)3-9 null mutants, concentration of HP1 at the chromocentre is nearly lost without affecting HP1 accumulation at the fourth chromosome. By contrast, in HP1 null mutants SU(VAR)3-9 is no longer restricted at heterochromatin but broadly dispersed across the chromosomes. Despite this interdependence, Su(var)3-9 dominates the PEV modifier effects of HP1 and Su(var)3-7 and is also epistatic to the Y chromosome effect on PEV. Finally, the human SUV39H1 gene is able to partially rescue Su(var)3-9 silencing defects. Together, these data indicate a central role for the SU(VAR)3-9 HMTase in heterochromatin-induced gene silencing in Drosophila.     

Molecular genetic characterization of a Korean split hand/split foot malformation (SHFM)

Split hand/split foot malformation (SHFM; ectrodactyly) is genetically heterogeneous, with mutations identified at five loci (SHFM1 at 7q21.3, SHFM2 at Xq26, SHFM3 at 10q24, SHFM4 at 3q27 and SHFM5 at 2q31). In this study, we attempted to identify and localize the causative allele of a Korean case of SHFM. Pedigree analysis showed that the Korean SHFM was autosomally dominant and its penetrance was high, indicating that it was not caused by SHFM2. Clinical features were variable, but limited to the four limbs unlike SHFM1, SHFM4 and SHFM5. G-banding and FISH failed to identify any chromosomal abnormalities. We also performed mutation screening by SSCP and DNA sequencing, as well as loss of heterozygosity (LOH) analysis, to exclude the possibility that SHFM4 or SHFM5 were involved; these revealed no mutations in gene p63 and no LOH on 2q31, respectively. It therefore appears that the Korean SHFM may be caused by mutation of SHFM3. In fact, linkage analysis using informative microsatellite markers indicated that SHFM3 was linked to D10S577 with a maximum LOD score of 1.15 at recombination fraction zero. Finally, we identified two novel alleles (191 and 211 bp) of D10S577 that have not been found in Western populations.     

SU(VAR)3-9 is a conserved key function in heterochromatic gene silencing

This review summarizes genetic, molecular and biochemical studies of the SU(VAR)3-9 protein and the evidence for its key role in heterochromatin formation and heterochromatic gene silencing. The Su(var)3-9 locus was first identified as a dominant modifier of position-effect variegation (PEV) in Drosophila melanogaster. Together with Su(var)2-5 and Su(var)3-7, Su(var)3-9 belongs to the group of haplo-suppressor loci which show a triplo-dependent enhancer effect. All three genes encode heterochromatin-associated proteins. Su(var)3-9 is epistatic to the PEV modifier effects of Su(var)2-5 and Su(var)3-7, and it also dominates the effect of the Y chromosome on PEV. These genetic data support a central role of the SU(VAR)3-9 protein in heterochromatic gene silencing, one that is correlated with its activity as a histone H3-K9 methyltransferase (HMTase). In fact, SU(VAR)3-9 is the main chromocenter-specific HMTase of Drosophila. SU(VAR)3-9 and HP1, the product of Su(var)2-5, are main constituents of heterochromatin protein complexes and the interaction between these two proteins is interdependent. Functional analysis in fission yeast, Drosophila and mammals demonstrate that SU(VAR)3-9-dependent gene silencing processes are conserved in these organisms. This is also demonstrated by the rescue of Drosophila Su(var)3-9 mutant phenotypes with human SUV39H1 transgenes.     

The association of split hand foot malformation (SHFM) and congenital heart defects

BACKGROUND: Split hand foot malformation (SHFM) (cleft hand, central ray deficiency) is a highly variable malformation that shows genetic heterogeneity with at least five loci mapped to date. SHFM occurs as an isolated finding or in association with other anomalies, including congenital heart defects (CHDs). METHODS: In total 48 SHFM1, 52 SHFM3, 48 SHFM4, 21 SHFM5, and four chromosome 8 patients were evaluated. In addition, we performed a literature review to identify “unmapped” SHFM patients with CHD to evaluate the various etiologies of this combination of findings. The London Dysmorphology Database also served as a resource to identify syndromes with this combination of phenotypic findings. Only patients presenting with both SHFM and CHD were included in the analysis. Classification of CHD among mapped and unmapped SHFM patients was performed utilizing the revised Clark classification. A closer inspection of the types of CHD found in this patient group was performed in order to investigate possible pathogenetic mechanisms. RESULTS: CHDs were found in 10% of SHFM1 patients, 47% of SHFM5 patients, but were not reported in SHFM2, SHFM4 patients, or patients mapped to chromosome 8. Forty‐two syndromic cases and 15 cases of unrecognized syndromes were identified. CONCLUSIONS: The higher frequency of heart defects seen in SHFM1 and SHFM5 of the mapped patient group raises the question as to whether common mechanisms/genetic players are involved. Candidate genes for SHFM1 and SHFM5 include members of the DLX homeobox gene family. Birth Defects Research (Part A), 2008. © 2008 Wiley‐Liss, Inc.     

Genomic rearrangement at 10q24 in non-syndromic split-hand/split-foot malformation

Split-hand/split-foot malformation (SHFM) is a congenital limb malformation characterized by a median cleft of hand and/or foot due to the absence of central rays. Five loci for syndromic and non-syndromic SHFM, termed SHFM1-5, have been mapped to date. Recently, a 0.5 Mb tandem genomic duplication was found at chromosome 10q24 in SHFM3 families. To refine the minimum duplicated region and to further characterize the SHFM3 locus, we screened 28 non-syndromic SHFM families for tandem genomic duplication of 10q24 by Southern blot and sequence analysis of the dactylin gene. Of 28 families, only two showed genomic rearrangements. Representative patients from the two families exhibit typical SHFM, with symmetrically affected hands and feet. One patient is a familial case with a 511,661 bp tandem duplication, whereas the second is a sporadic case arising from a de novo, 447,338 bp duplication of maternal origin. The smaller duplication in the second patient contained the LBX1, BTRC, POLL, and DPCD genes and a disrupted extra copy of the dactylin gene, and was nearly identical to the smallest known duplicated region of SHFM3. Our results indicate that genomic rearrangement of SHFM3 is rare among non-syndromic SHFM patients and emphasize the importance of screening for genomic rearrangements even in sporadic cases of SHFM.     

细胞凋亡过程中c-erbB-2基因的表达

据文献报道ｃ－ｅｒｂＢ－２可以介导细胞凋亡,为检验这一结论是否具有普遍性,用５－氟尿嘧啶（５－Ｆｕ）诱导小鼠成纤维细胞ＮＣ３Ｈ１０,ＴＣ３Ｈ１０及人乳腺癌细胞ＭＣＦ－７的凋亡．用Ｎｏｒｔｈｅｒｎ印迹法检测ｃ－ｅｒｂＢ－２的表达状况．结果显示：ｃ－ｅｒｂＢ－２基因表达在５－Ｆｕ作用６ｈ开始降低,１２ｈ降低更为明显．作用２４～４８ｈ出现细胞存活率下降,ＤＮＡ梯状断裂及细胞周期凋亡峰等凋亡典型现象．实验结果并不支持ｃ－ｅｒｂＢ－２可介导细胞凋亡的观点．该基因在细胞凋亡过程中有何作用尚待探讨．     

Modulation of the Suppressor of fused protein regulates the Hedgehog signaling pathway in Drosophila embryo and imaginal discs

The Suppressor of fused (Su(fu)) protein is known to be a negative regulator of Hedgehog (Hh) signal transduction in Drosophila imaginal discs and embryonic development. It is antagonized by the kinase Fused (Fu) since Su(fu) null mutations fully suppress the lack of Fu kinase activity. In this study, we overexpressed the Su(fu) gene in imaginal discs and observed opposing effects depending on the position of the cells, namely a repression of Hh target genes in cells receiving Hh and their ectopic expression in cells not receiving Hh. These effects were all enhanced in a fu mutant context and were suppressed by cubitus interruptus (Ci) overexpression. We also show that the Su(fu) protein is poly-phosphorylated during embryonic development and these phosphorylation events are altered in fu mutants. This study thus reveals an unexpected role for Su(fu) as an activator of Hh target gene expression in absence of Hh signal. Both negative and positive roles of Su(fu) are antagonized by Fused. Based on these results, we propose a model in which Su(fu) protein levels and isoforms are crucial for the modulation of the different Ci states that control Hh target gene expression.     

小鼠成纤维细胞凋亡过程中P53与bcl-2表达的时序性

为探讨细胞凋亡过程中,ｂｃｌ－２与Ｐ５３,这两种凋亡关键性基因的相互关系,用５－氟尿嘧啶（５－Ｆｕ）诱导小鼠正常与恶性转化的成纤维细胞的凋亡,观察了这两种基因在凋亡过程中表达变化的时序．经流式细胞计检测,这两种细胞在５－Ｆｕ作用２４ｈ均出现了凋亡峰,细胞存活率随之下降,ＤＮＡ电泳显现梯状断裂．Ｎｏｒｔｈｅｒｎ杂交结果显示,在５－Ｆｕ作用６ｈ后两种细胞Ｐ５３ｍＲＮＡ水平已明显增高,而ｂｃｌ－２ｍＲＮＡ水平则在作用１２ｈ方明显降低．Ｐ５３上调与ｂｃｌ－２下调的明显时序性,说明Ｐ５３具备作为ｂｃｌ－２基因负调控转录因子的条件．由此,为进一步了解凋亡过程的ｂｃｌ－２基因下调机理提供了线索     

Triphalangeal thumb in association with split hand/foot: A phenotypic marker for SHFM3?

BACKGROUND: At least five distinct loci have been implicated in split hand foot malformation (SHFM). Establishing genotype/phenotype correlations at the chromosomal level may elucidate responsible developmental genes and improve patient management. In our analysis of previously published genetically mapped SHFM cases, preaxial hand involvement was a significant discriminating variable, most commonly seen at the SHFM3 locus (OMIM 600095) at 10q24. Of the 47 SHFM3 patients analyzed, 15 (31.9%) had triphalangeal thumb (TPT), a limb finding not reported at any other locus. METHODS: The association of TPT/split foot, in particular, prompted us to review the literature for similar cases. RESULTS: We ascertained a number of unmapped familial and sporadic cases with TPT/split foot, including a group of patients with triphalangeal thumb-brachyectrodactyly syndrome. Certain trends were similar in both SHFM3 and these unmapped literature cases. With respect to gender, 7/12 (58%) of mapped SHFM3 cases with TPT/split foot were male whereas 5/12 (42%) were female, compared with 22/50 (44%) males and 28/50 (56%) females among unmapped cases (P=0.3715). Individuals in both groups usually had bilateral involvement, with 67 and 60% showing bilateral TPT among mapped and literature cases, respectively (P=0.6714). Bilateral involvement of the feet was even more striking (83% of SHFM3 patients and 96% of literature cases; P=0.0808). CONCLUSIONS: Patients with TPT/split foot may in fact represent SHFM3 cases and should be evaluated for genomic rearrangements at 10q24. TPT may be identified only by radiographic analysis, emphasizing the importance of imaging these patients and their family members.     

Fine mapping of the split-hand/split-foot locus (SHFM3) at 10q24: evidence for anticipation and segregation distortion.

Split-hand/split-foot malformation (SHFM, ectrodactyly, or lobster-claw deformity) is a human limb malformation characterized by aberrant development of central digital rays with absence of fingers and toes, a deep median cleft, and fusion of remaining digits. SHFM is clinically heterogeneous, presenting both in an isolated form and in combination with additional abnormalities affecting the tibia and/or other organ systems, including the genitourinary, craniofacial, and ectodermal structures. Three SHFM disease loci have been genetically mapped to chromosomes 7q21 (SHFM1), Xq26 (SHFM2), and 10q24 (SHFM3). We mapped data from a large Turkish family with isolated SHFM to chromosome 10q24 and have narrowed the SHFM3 region from 9 cM to an approximately 2-cM critical interval between genetic markers D10S1147 and D10S1240. In several instances we found evidence for a more severe phenotype in offspring of a mildly affected parent, suggesting anticipation. Finally, data from this family, combined with those from six other pedigrees, mapped to 10q24, demonstrate biased transmission of SHFM3 alleles from affected fathers to offspring. The degree of this segregation distortion is obvious in male offspring and is possibly of the same magnitude for female offspring.     

细胞凋亡过程中bcl-2基因的甲基化

为探讨凋亡过程中,ｂｃｌ－２基因下调与该基因甲基化状态的关系,用５－氟尿嘧啶（５－Ｆｕ）诱导小鼠成纤维细胞ＮＣ３Ｈ１０,ＴＣ３Ｈ１０及人乳腺癌细胞ＭＣＦ－７的凋亡,分别检测了这三种细胞凋亡过程中ｂｃｌ－２的表达变化,与其调控区及编码区的甲基化状况．我们曾观察到５－Ｆｕ作用２４～４８ｈ出现细胞存活率下降,ＤＮＡ梯状断裂及细胞周期凋亡峰显现等典型凋亡现象．Ｎｏｒｔｈｅｒｎ杂交显示,在５－Ｆｕ作用１２ｈ时ｂｃｌ－２ｍＲＮＡ水平已明显降低．由此,我们用小鼠ｂｃｌ－２（ｍｂｃｌ－２）及人ｂｃｌ－２（ｈｂｃｌ－２）基因调控区ＰＣＲ扩增片段及ｂｃｌ－２编码区（ｃＤＮＡ）片段作为探针,与５－Ｆｕ作用１２ｈ的细胞ＤＮＡ的ＭｓｐⅠ／ＨｐａⅡ酶切产物进行Ｓｏｕｔｈｅｒｎ杂交,以未作用的细胞ＤＮＡ同样酶切杂交为对照．通过杂交带谱的变化,分析ｂｃｌ－２基因的甲基化状况．结果显示：ｍｂｃｌ－２及ｈｂｃｌ－２在５－Ｆｕ作用１２ｈ后调控区甲基化水平增高,但其编码区甲基化状态皆未出现可检出的变化．上述结果提示：ｂｃｌ－２基因调控区甲基化水平升高可能与该基因下调有关     

Heterochromatin formation in Drosophila is initiated through active removal of H3K4 methylation by the LSD1 homolog SU(VAR)3-3

Epigenetic indexing of chromatin domains by histone lysine methylation requires the balanced coordination of methyltransferase and demethylase activities. Here, we show that SU(VAR)3-3, the Drosophila homolog of the human LSD1 amine oxidase, demethylates H3K4me2 and H3K4me1 and facilitates subsequent H3K9 methylation by SU(VAR)3-9. Su(var)3-3 mutations suppress heterochromatic gene silencing, display elevated levels of H3K4me2, and prevent extension of H3K9me2 at pericentric heterochromatin. SU(VAR)3-3 colocalizes with H3K4me2 in interband regions and is abundant during embryogenesis and in syncytial blastoderm, where it appears concentrated at prospective heterochromatin during cycle 14. In embryos of Su(var)3-3/+ females, H3K4me2 accumulates in primordial germ cells, and the deregulated expansion of H3K4me2 antagonizes heterochromatic H3K9me2 in blastoderm cells. Our data indicate an early developmental function for the SU(VAR)3-3 demethylase in controlling euchromatic and heterochromatic domains and reveal a hierarchy in which SU(VAR)3-3-mediated removal of activating histone marks is a prerequisite for subsequent heterochromatin formation by H3K9 methylation.     

Inhibition of circular RNA CDR1as increases chemosensitivity of 5‐FU‐resistant BC cells through up‐regulating miR‐7

This study aims to explore the mechanism of Circular RNA CDR1as implicating in regulating 5‐fluorouracil (5‐FU) chemosensitivity in breast cancer (BC) by competitively inhibiting miR‐7 to regulate CCNE1. Expressions of CDR1as and miR‐7 in 5‐FU‐resistant BC cells were determined by RT‐PCR. CCK‐8, colony formation assay and flow cytometry were applied to measure half maximal inhibitory concentration (IC50), 5‐Fu chemosensitivity and cell apoptosis. Western blot was used to detect the expressions of apoptosis‐related factors. CDR1as was elevated while miR‐7 was inhibited in 5‐FU‐resistant BC cells. Cells transfected with si‐CDR1as or miR‐7 mimic had decreased IC50 and colony formation rate, increased expressions of Bax/Bcl2 and cleaved‐Caspase‐3/Caspase‐3, indicating inhibition of CDR1as and overexpression of miR‐7 enhances the chemosensitity of 5‐FU‐resistant BC cells. Targetscan software indicates a binding site of CDR1as and miR‐7 and that CCNE1 is a target gene of miR‐7. miR‐7 can gather CDR1as in BC cells and can inhibit CCNE1. In comparison to si‐CDR1as group, CCNE1 was increased and chemosensitivity to 5‐Fu was suppressed in si‐CDR1as + miR‐7 inhibitor group. When compared with miR‐7 mimic group, CDR1as + miR‐7 mimic group had increased CCNE1 and decreased chemosensitivity to 5‐Fu. Nude mouse model of BC demonstrated that the growth of xenotransplanted tumour in si‐CDR1as + miR‐7 inhibitor group was faster than that in si‐CDR1as group. The tumour growth in CDR1as + miR‐7 mimic group was faster than that in miR‐7 mimic group. CDR1as may regulate chemosensitivity of 5‐FU‐resistant BC cells by inhibiting miR‐7 to regulate CCNE1.