Tianxiao Huang scite author profile

Twenty‐four nucleotide long microRNAs (lmiRNAs) direct DNA methylation at target genes and regulate their transcription. The evolutionary origin of lmiRNAs and the range of lmiRNA‐mediated regulation remain obscure. Here, we reannotated lmiRNAs and their targets in rice by applying stringent criteria. We found that the majority of lmiRNAs are derived from Miniature Inverted‐repeat Transposable Elements (MITEs) and most sites targeted by MITE‐derived lmiRNAs reside within MITEs, suggesting co‐evolution of lmiRNAs and their targets through MITE amplification. lmiRNAs undergo dynamically changes under stress conditions and the genes targeted by lmiRNAs show an enrichment for stress‐responsive genes, suggesting that lmiRNAs are widely involved in plant responses to stresses. We constructed the evolutionary histories of lmiRNAs and their targets. Nearly half of lmiRNAs emerged before or when the AA genome was diverged, while the emergence of lmiRNA targets coincided with or followed the emergence of lmiRNAs. Furthermore, we found that the sequences of a lmiRNA target site underwent variations, coincident with the divergence of rice accessions and the distribution of rice accessions in different geographical locations and climatic conditions. Our findings highlight MITEs as an important origin of lmiRNAs and suggest that the evolution of lmiRNA‐target regulatory modules may contribute to rice adaptation to environmental changes.

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Monoamine and neuropeptide connections significantly alter the degree distributions of the Caenorhabditis elegans connectome

Huang

Sun²,

Zhang³

et al. 2017

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To understand the behaviors of an individual, it is crucial to understand the neural connections of the nervous system, that is, the connectome. The hermaphrodite Caenorhabditis elegans connectome has served as a prototype for analytical studies since the chemical synapses and gap junctions among the 302 neurons were completely mapped. Recently, monoamine (MA) and neuropeptide (NP) connections were established, which form a multilayer connectome in conjunction with chemical synapses and gap junctions. In this study, we investigated the difference in the in-degree and out-degree distributions, respectively, among the connectomes with and without MA and NP connections. We found that the in-degree and out-degree distributions show different properties of dissimilarity. We discovered that only a few of the degree distributions can be fitted perfectly to power-law or exponential models. Finally, clustering analysis suggests that MA and NP connections significantly alter the degree distributions of the C. elegans connectome. Overall, our study provides an insight into the structural properties of the multilayer connectome with MA and NP connections and confirms the necessity to investigate the multilayer connectome to understand the behaviors of a worm.

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Tianxiao Huang

N6-methyldeoxyadenine is a transgenerational epigenetic signal for mitochondrial stress adaptation

Dead lithium formation in lithium metal batteries: A phase field model

Evolution of lmiRNAs and their targets from MITEs for rice adaptation

Monoamine and neuropeptide connections significantly alter the degree distributions of the Caenorhabditis elegans connectome

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