lncRNA SNHG3 facilitates acute myeloid leukemia cell growth via the regulation of miR-758-3p/SRGN axis.

Small nucleolar RNA host gene 3 (SNHG3) is a newly identified long non-coding RNA whose dysregulation has been reported in several cancers. However, the details about clinical significances and biological functions of SNHG3 on acute myeloid leukemia (AML) remain covered. In this study, we revealed increased SNHG3 expression in AML samples and cells and its high potential as a prognostic biomarker for AML patients. Likewise, serglycin (SRGN), which plays an important role in granule-mediated apoptosis, was previously verified to be upregulated in AML and confirmed again by the present study, and its upregulation predicted poor outcomes in AML. Furthermore, knockdown of SNHG3 or SRGN inhibited cell proliferation and induced cell apoptosis. Besides, silencing SNHG3 noticeably decreased the expression of SRGN in AML cells. Moreover, we uncovered that SNHG3 modulated SRGN expression by competitively binding with miR-758-3p. Importantly, both miR-758-3p suppression and SRGN overexpression could mitigate the inhibitory effects of SNHG3 depletion on AML cell growth. Intriguingly, the higher SRGN expression in AML samples with a higher SNHG3 level exhibited an enhanced Ki67 level but a reduced caspase 3 level. To sum up, SNHG3 elicits a growth-promoting function in AML via sponging miR-758-3p to regulate SRGN expression, providing a new therapeutic road for AML patients.

All-Silicon Topological Semimetals with Closed Nodal Line.

Because of the natural compatibility with current semiconductor industry, silicon allotropes with diverse structural and electronic properties provide promising platforms for next-generation Si-based devices. After screening 230 all-silicon crystals in the zeolite frameworks by first-principles calculations, we disclose two structurally stable Si allotropes (AHT-Si24 and VFI-Si36) containing open channels as topological node-line semimetals with Dirac nodal points forming a nodal loop in the k z = 0 plane of the Brillouin zone. Interestingly, their nodal loops protected by inversion and time-reversal symmetries are robust against SU(2) symmetry breaking because of the very weak spin-orbit coupling of Si. When the nodal lines are projected onto the (001) surface, flat surface bands can be observed because of the nontrivial topology of the bulk band structures. Our discoveries extend the topological physics to the three-dimensional Si materials, highlighting the possibility of realizing low-cost, nontoxic, and semiconductor-compatible Si-based electronics with topological quantum states.