5.9
CiteScore
5.9
Impact Factor

2013 Vol. 40, No. 11

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Review
Sperm Mitochondria in Reproduction: Good or Bad and Where Do They Go?
Shi-Ming Luo, Heide Schatten, Qing-Yuan Sun
2013, 40(11): 549-556. doi: 10.1016/j.jgg.2013.08.004
Abstract (114) HTML PDF (3)
Abstract:
The mitochondrion is the major energy provider to power sperm motility. In mammals, aside from the nuclear genome, mitochondrial DNA (mtDNA) also contributes to oxidative phosphorylation to impact production of ATP by coding 13 polypeptides. However, the role of sperm mitochondria in fertilization and its final fate after fertilization are still controversial. The viewpoints that sperm bearing more mtDNA will have a better fertilizing capability and that sperm mtDNA is actively eliminated during early embryogenesis are widely accepted. However, this may be not true for several mammalian species, including mice and humans. Here, we review the sperm mitochondria and their mtDNA in sperm functions, and the mechanisms of maternal mitochondrial inheritance in mammals.
Original research
Generation of Hematopoietic Stem Cells from Purified Embryonic Endothelial Cells by a Simple and Efficient Strategy
Zhuan Li, Fan Zhou, Dongbo Chen, Wenyan He, Yanli Ni, Lingfei Luo, Bing Liu
2013, 40(11): 557-563. doi: 10.1016/j.jgg.2013.09.001
Abstract (137) HTML PDF (0)
Abstract:
Recent progress by versatile approaches supports the new hypothesis that multi-potent hematopoietic stem cells (HSCs) are directly formed from a rare population of endothelial cells in mid-gestation mouse embryos. This process is therefore known as the endothelial-to-hematopoietic transition (EHT). Nevertheless, there is no functional evidence that documents the HSC transition from purified endothelial cells. In this study, we developed an OP9-DL1-based co-culture system that was able to facilitate the HSC specification and/or expansion in vitro of mouse embryonic day 10.5 (E10.5) Tie2+ cells remarkably. Then, the immunophenotypically defined endothelial cells were harvested by a combination of surface markers (Flk1+CD31+CD41CD45Ter119) from the caudal half of E10.0–E11.0 mouse embryos. The transplantation of the endothelia/OP9-DL1 co-cultures led to long-term, high-level, multi-lineage, and multi-organ hematopoietic reconstitution in the irradiated adult recipients. The induced HSC activity was initially observed at E10.5, and a significant increase was detected at E11.0, which suggests a temporally specific regulation. Taken together, for the first time, we provide functional evidence showing the HSC potential of purified embryonic endothelial cells, which is indispensable for the emerging EHT concept. Moreover, the newly defined co-culture system will aid the exploration of the key molecules governing the HSC transition from embryonic and even postnatal endothelial cells, which has enormous significance in basic and translational research.
Sequence Diversity and Enzyme Activity of Ferric-Chelate Reductase LeFRO1 in Tomato
Danyu Kong, Chunlin Chen, Huilan Wu, Ye Li, Junming Li, Hong-Qing Ling
2013, 40(11): 565-573. doi: 10.1016/j.jgg.2013.08.002
Abstract (100) HTML PDF (1)
Abstract:
Ferric-chelate reductase which functions in the reduction of ferric to ferrous iron on root surface is a critical protein for iron homeostasis in strategy I plants. LeFRO1 is a major ferric-chelate reductase involved in iron uptake in tomato. To identify the natural variations of LeFRO1 and to assess their effect on the ferric-chelate reductase activity, we cloned the coding sequences of LeFRO1 from 16 tomato varieties collected from different regions, and detected three types of LeFRO1 (LeFRO1MM, LeFRO1Ailsa and LeFRO1Monita) with five amino acid variations at the positions 21, 24, 112, 195 and 582. Enzyme activity assay revealed that the three types of LeFRO1 possessed different ferric-chelate reductase activity (LeFRO1Ailsa > LeFRO1MM > LeFRO1Monita). The 112th amino acid residue Ala of LeFRO1 is critical for maintaining the high activity of ferric-chelate reductase, because modification of this amino acid resulted in a significant reduction of enzyme activity. Further, we showed that the combination of the amino acid residue Ile at the site 24 with Lys at the site 582 played a positive role in the enzyme activity of LeFRO1. In conclusion, the findings are helpful to understand the natural adaptation mechanisms of plants to iron-limiting stress, and may provide new knowledge to select and manipulate LeFRO1 for improving the iron deficiency tolerance in tomato.
Letter to the Editor
MYPT1 Sustains Centromeric Cohesion and the Spindle-Assembly Checkpoint
Jing Li, Xiaoqian Liu, Ji Liao, Jie Tian, Jue Wang, Xin Wang, Jiezhong Zhang, Xingzhi Xu
2013, 40(11): 575-578. doi: 10.1016/j.jgg.2013.08.005
Abstract (75) HTML PDF (0)
Abstract:
Characterization and Fine Mapping of GLABROUS RICE 2 in Rice
Yuping Wang, Weilan Chen, Peng Qin, Yanyan Huang, Bingtian Ma, Xinhao Ouyang, Xuewei Chen, Shigui Li
2013, 40(11): 579-582. doi: 10.1016/j.jgg.2013.06.001
Abstract (77) HTML PDF (9)
Abstract: