Resting‐state networks of the neonate brain identified using independent component analysis

Resting‐state functional magnetic resonance imaging (rs‐fMRI) has been successfully used to probe the intrinsic functional organization of the brain and to study brain development. Here, we implemented a combination of individual and group independent component analysis (ICA) of FSL on a 6‐min resting‐state data set acquired from 21 naturally sleeping term‐born (age 26 ± 6.7 d), healthy neonates to investigate the emerging functional resting‐state networks (RSNs). In line with the previous literature, we found evidence of sensorimotor, auditory/language, visual, cerebellar, thalmic, parietal, prefrontal, anterior cingulate as well as dorsal and ventral aspects of the default‐mode‐network. Additionally, we identified RSNs in frontal, parietal, and temporal regions that have not been previously described in this age group and correspond to the canonical RSNs established in adults. Importantly, we found that careful ICA‐based denoising of fMRI data increased the number of networks identified with group‐ICA, whereas the degree of spatial smoothing did not change the number of identified networks. Our results show that the infant brain has an established set of RSNs soon after birth.     

Decomposing complex reaction networks using random sampling,principal component analysis and basis rotation

Background  

Metabolism and its regulation constitute a large fraction of the molecular activity within cells. The control of cellular metabolic state is mediated by numerous molecular mechanisms, which in effect position the metabolic network flux state at specific locations within a mathematically-definable steady-state flux space. Post-translational regulation constitutes a large class of these mechanisms, and decades of research indicate that achieving a network flux state through post-translational metabolic regulation is both a complex and complicated regulatory problem. No analysis method for the objective, top-down assessment of such regulation problems in large biochemical networks has been presented and demonstrated.     

基于卷积神经网络的细菌转录终止子预测

在遗传学中,终止子是位于poly(A)位点下游、长度在数百碱基以内、包含多个回文序列、具有终止转录功能的DNA结构域,其主要作用是使转录终止。在原核生物基因组中有两类转录终止子,即Rho-dependent因子和Rho-independent因子。在本项研究中,提出了一种新的预测模型(TermCNN)来快速准确地识别细菌转录终止子。该模型将具有代表性的6-mer特征子集(2 537个特征)和电子—离子相互作用伪电位(EIIP)作为输入向量,利用卷积神经网络(CNN)构建预测模型。五折交叉验证和独立测试的结果表明该模型优于最新的预测模型iTerm-PseKNC。值得注意的是,该模型在跨物种试验中具有明显的优势。它可以高度精确地预测大肠杆菌(E. coli)和枯草芽孢杆菌(B. subtilis)的转录终止子。