2016 Vol. 7(1)

Recollection
Jian-Kang Liu: A pioneer of sex determination studies in vertebrates
Li Zhou, Jian-Fang Gui
2016, 7(1): 1-3. doi: 10.1007/s13238-015-0232-7
Abstract:
Commentaries
Can Ebola virus become endemic in the human population?
Gary Wong, George F. Gao, Xiangguo Qiu
2016, 7(1): 4-6. doi: 10.1007/s13238-015-0231-8
Abstract:
Human germ line editing—roles and responsibilities
Jeantine E. Lunshof
2016, 7(1): 7-10. doi: 10.1007/s13238-015-0224-7
Abstract:
Reviews
Mitochondrial DNA in the regulation of innate immune responses
Chunju Fang, Xiawei Wei, Yuquan Wei
2016, 7(1): 11-16. doi: 10.1007/s13238-015-0222-9
Abstract:
Mitochondrion is known as the energy factory of the cell, which is also a unique mammalian organelle and considered to be evolved from aerobic prokaryotes more than a billion years ago. Mitochondrial DNA, similar to that of its bacterial ancestor's, consists of a circular loop and contains significant number of unmethylated DNA as CpG islands. The innate immune system plays an important role in the mammalian immune response. Recent research has demonstrated that mitochondrial DNA (mtDNA) activates several innate immune pathways involving TLR9, NLRP3 and STING signaling, which contributes to the signaling platforms and results in effector responses. In addition to facilitating antibacterial immunity and regulating antiviral signaling, mounting evidence suggests that mtDNA contributes to inflammatory diseases following cellular damage and stress. Therefore, in addition to its well-appreciated roles in cellular metabolism and energy production, mtDNA appears to function as a key member in the innate immune system. Here, we highlight the emerging roles of mtDNA in innate immunity.
Thermodynamics of ABC transporters
Xuejun C. Zhang, Lei Han, Yan Zhao
2016, 7(1): 17-27. doi: 10.1007/s13238-015-0211-z
Abstract:
ABC transporters form the largest of all transporter families, and their structural study has made tremendous progress over recent years. However, despite such advances, the precise mechanisms that determine the energy-coupling between ATP hydrolysis and the conformational changes following substrate binding remain to be elucidated. Here, we present our thermodynamic analysis for both ABC importers and exporters, and introduce the two new concepts of differential-binding energy and elastic conformational energy into the discussion. We hope that the structural analysis of ABC transporters will henceforth take thermodynamic aspects of transport mechanisms into account as well.
Hemagglutinin-esterase-fusion (HEF) protein of influenza C virus
Mingyang Wang, Michael Veit
2016, 7(1): 28-45. doi: 10.1007/s13238-015-0193-x
Abstract:
Influenza C virus, a member of the Orthomyxoviridae family, causes flu-like disease but typically only with mild symptoms. Humans are the main reservoir of the virus, but it also infects pigs and dogs. Very recently, influenza C-like viruses were isolated from pigs and cattle that differ from classical influenza C virus and might constitute a new influenza virus genus. Influenza C virus is unique since it contains only one spike protein, the hemagglutinin-esterase-fusion glycoprotein HEF that possesses receptor binding, receptor destroying and membrane fusion activities, thus combining the functions of Hemagglutinin (HA) and Neuraminidase (NA) of influenza A and B viruses. Here we briefly review the epidemiology and pathology of the virus and the morphology of virus particles and their genome. The main focus is on the structure of the HEF protein as well as on its co-and posttranslational modification, such as N-glycosylation, disulfide bond formation, S-acylation and proteolytic cleavage into HEF1 and HEF2 subunits. Finally, we describe the functions of HEF:receptor binding, esterase activity and membrane fusion.
Research articles
A local-optimization refinement algorithm in single particle analysis for macromolecular complex with multiple rigid modules
Hong Shan, Zihao Wang, Fa Zhang, Yong Xiong, Chang-Cheng Yin, Fei Sun
2016, 7(1): 46-62. doi: 10.1007/s13238-015-0229-2
Abstract:
Single particle analysis, which can be regarded as an average of signals from thousands or even millions of particle projections, is an efficient method to study the three-dimensional structures of biological macromolecules. An intrinsic assumption in single particle analysis is that all the analyzed particles must have identical composition and conformation. Thus specimen heterogeneity in either composition or conformation has raised great challenges for high-resolution analysis. For particles with multiple conformations, inaccurate alignments and orientation parameters will yield an averaged map with diminished resolution and smeared density. Besides extensive classification approaches, here based on the assumption that the macromolecular complex is made up of multiple rigid modules whose relative orientations and positions are in slight fluctuation around equilibriums, we propose a new method called as local optimization refinement to address this conformational heterogeneity for an improved resolution. The key idea is to optimize the orientation and shift parameters of each rigid module and then reconstruct their three-dimensional structures individually. Using simulated data of 80S/70S ribosomes with relative fluctuations between the large (60S/50S) and the small (40S/30S) subunits, we tested this algorithm and found that the resolutions of both subunits are significantly improved. Our method provides a proof-of-principle solution for high-resolution single particle analysis of macromolecular complexes with dynamic conformations.
SENP3 regulates the global protein turnover and the Sp1 level via antagonizing SUMO2/3-targeted ubiquitination and degradation
Ming Wang, Jing Sang, Yanhua Ren, Kejia Liu, Xinyi Liu, Jian Zhang, Haolu Wang, Jian Wang, Amir Orian, Jie Yang, Jing Yi
2016, 7(1): 63-77. doi: 10.1007/s13238-015-0216-7
Abstract:
SUMOylation is recently found to function as a targeting signal for the degradation of substrates through the ubiquitin-proteasome system. RNF4 is the most studied human SUMO-targeted ubiquitin E3 ligase. However, the relationship between SUMO proteases, SENPs, and RNF4 remains obscure. There are limited examples of the SENP regulation of SUMO2/3-targeted proteolysis mediated by RNF4. The present study investigated the role of SENP3 in the global protein turnover related to SUMO2/3-targeted ubiquitination and focused in particular on the SENP3 regulation of the stability of Sp1. Our data demonstrated that SENP3 impaired the global ubiquitination profile and promoted the accumulation of many proteins. Sp1, a cancer-associated transcription factor, was among these proteins. SENP3 increased the level of Sp1 protein via antagonizing the SUMO2/3-targeted ubiquitination and the consequent proteasome-dependent degradation that was mediated by RNF4. De-conjugation of SUMO2/3 by SENP3 attenuated the interaction of Sp1 with RNF4. In gastric cancer cell lines and specimens derived from patients and nude mice, the level of Sp1 was generally increased in parallel to the level of SENP3. These results provided a new explanation for the enrichment of the Sp1 protein in various cancers, and revealed a regulation of SUMO2/3 conjugated proteins whose levels may be tightly controlled by SENP3 and RNF4.

Current Issue

May, 2019

Volume 10, Issue 5

Pages 313-387

About the cover

Left image:a mouse E9.5 embryo with Dgcr8 microRNA microprocessor conditionally knocked out in the heart. The heart in green was extremely dilated. Top right:cTnT immunostaining (in green) showed that the heart had very thin wall. Middle right:cTnT immunostaining (in red) showed lack of sarcomere structure in a microRNA free cardiomyocyte (CM). Insert:slow calcium transient frequency. Bottom right: transfection of miR-541 rescued sarcomere structure in Dgcr8 cKO CMs. cTnT immunostaining (in red) showed typical sarcomere structure. Insert:fast calcium transient frequency.

Institute of Biophysics, Chinese Academy of Sciences, 15 Datun Road, Chaoyang Beijing 100101, China

Tel: (86-10) 64888620   Fax: (86-10) 64880586   E-mail: protein_cell@biols.ac.cn