ß2 integrin-derived signals induce cell survival and proliferation of AML blasts by activating a Syk/STAT signaling axis.

Spleen tyrosine kinase (Syk) induces cell survival and proliferation in a high proportion of acute myeloid leukemia (AML) blasts, but the underlying molecular events of Syk signaling have not been investigated. Proteomic techniques have allowed us to identify the multiprotein complex that is nucleated by constitutively active Syk in AML cells. This complex differs from the B-lymphoid Syk interactome with respect to several proteins, especially the integrin receptor Mac-1, the Fc-γ receptor I (FcγRI), and the transcription factors STAT3 and STAT5. We show in several AML cell line models that tonic signals derived from the Fc-γ chain lead to Syk-dependent activation of STAT3 and STAT5, which in turn induces cell survival and proliferation. Moreover, stimulation of Mac-1 or FcγRI intensifies the constitutive Syk-mediated STAT3/5 activation in AML cells, a scenario likely to take place in the bone marrow niche. In accordance with these findings, we observed that ß2 integrins, including Mac-1, trigger proliferation of AML cells in an AML cell/stroma coculture model. Taken together, we identified an oncogenic integrin/Syk/STAT3/5 signaling axis that might serve as a therapeutic target of AML in the future.

The pre-ovulatory luteinizing hormone surge is followed by down-regulation of CYP19A1, HSD3B1, and CYP17A1 and chromatin condensation of the corresponding promoters in bovine follicles.

The pre-ovulatory luteinizing hormone (LH) surge induces an extensive molecular, physiological, and morphological reorganization of the bovine follicle. This study was designed to elucidate if chromatin modulation is involved in the LH-induced gene regulation. Granulosa and theca of well-characterized large bovine follicles were isolated before and after the LH surge. CYP19A1, HSD3B1, and CYP17A1 transcripts, which encode key enzymes of steroid hormone biosynthesis, were quantified by real-time PCR (qPCR) and the degree of chromatin condensation was determined by DNase I protection assays. After LH, granulosa-specific CYP19A1 and theca-specific CYP17A1 transcripts were almost completely down-regulated. Also, the abundance of HSD3B1 transcripts was reduced. The promoter chromatin of HSD3B1 and particularly of CYP19A1 was significantly less accessible to DNAse I in both cell types after LH, whereas the chromatin accessibility of the CYP17A1 promoter changed only in the theca. Correlation analysis revealed partly, highly significant negative correlations between transcript abundance and protection from DNase I digestion of the corresponding chromatin. The data strongly suggest that LH induces cell type- and gene-specific chromatin condensation in the pre-ovulatory bovine follicle. This epigenetic mechanism might be involved in the pre-ovulatory down-regulation of genes.

DNA methylation is not involved in preovulatory down-regulation of CYP11A1, HSD3B1, and CYP19A1 in bovine follicles but may have a role in permanent silencing of CYP19A1 in large granulosa lutein cells.

The luteinizing hormone-induced morphological and physiological reorganization of the bovine follicle is preceded by a profound and well-orchestrated modulation of gene expression. In the present study, the cell type-specific methylation profiles of CYP11A1, HSD3B1, and CYP19A1, genes that encode key enzymes of steroid hormone biosynthesis, were analyzed to elucidate whether epigenetic parameters such as DNA methylation might be involved in gene regulation during luteinization. Transcript abundance and DNA methylation levels were determined in granulosa and theca of large dominant and late preovulatory follicles and in large granulosa lutein cells isolated from corpora lutea cyclica and graviditatis. Levels of the steroid hormones progesterone and estradiol-17beta were monitored to assess the physiological status of individual follicles. From our results, we conclude that (1) individual, even closely neighboring, CpG dinucleotides can show very different methylation levels; (2) proximal (<300 base pair [bp] from the respective transcription start sites) but not distal CpGs show cell type-specific methylation levels; (3) higher methylation levels suggestively preclude high levels of gene expression; (4) DNA methylation is not involved in the transient (HSD3B1 and CYP11A1) respectively permanent (CYP19A1) down-regulation of gene expression in late preovulatory follicles; and (5) DNA methylation may have a role in the permanent shutdown of promoter 2-directed CYP19A1 expression in large (granulosa derived) lutein cells.

Down-regulation of genes encoding steroidogenic enzymes and hormone receptors in late preovulatory follicles of the cow coincides with an accumulation of intrafollicular steroids.

The transformation of the dominant follicle into a functional corpus luteum is accompanied by a profound molecular and morphological reorganization of somatic cell layers. Several studies have focused on gene expression during early processes of follicular differentiation as it relates to recruitment and selection of dominant follicles. However, little information exists on changes of gene expression profiles in late preovulatory follicles. This lack of information is addressed here to elucidate molecular mechanisms behind the LH-induced transition from the large dominant estrogen-active to the preovulatory follicle, an intermediate stage toward full luteinization. Transcripts encoding key molecules for the biosynthesis of steroid hormones and prostaglandins, as well as receptors for gonadotropic and growth hormones (Star, Cyp11a1, Hsd3b, Cyp17, Cyp19, Ptgs2, Fshr, Lhr, and Ghr), were quantified by real-time polymerase chain reaction (PCR) in the granulosa and theca of large dominant and late preovulatory follicles. The steroid hormones progesterone (P4) and estradiol-17beta (E2) were monitored to distinguish estrogen-active and estrogen-inactive follicles. We found that (1) independent of the follicular stage, the gene expression profile was very different in granulosa and theca; (2) the abundance of several key transcripts was lower in estrogen-inactive, compared with estrogen-active, dominant follicles; (3) in the granulosa of late preovulatory follicles, transcripts encoding steroidogenic enzymes and hormone receptors were largely down-regulated, whereas (4) progesterone and E2 were found at high concentrations in the follicular fluid. Collectively, our data show that late preovulatory follicles have a transient and unique gene expression profile and are clearly different from both the preceding and subsequent (follicular and luteal, respectively) stages.