Verdoheme formation in Proteus mirabilis catalase

Background

Heme oxidative degradation has been extensively investigated in peroxidases but not in catalases. The verdoheme formation, a product of heme oxidation which inactivates the enzyme, was studied in Proteus mirabilis catalase.

Methods

The verdoheme was generated by adding peracetic acid and analyzed by mass spectrometry and spectrophotometry.

Results

Kinetics follow-up of different catalase reactional intermediates shows that i) the formation of compound I always precedes that of verdoheme, ii) compound III is never observed, iii) the rate of compound II decomposition is not compatible with that of verdoheme formation, and iv) dithiothreitol prevents the verdoheme formation but not that of compound II, whereas NADPH prevents both of them. The formation of verdoheme is strongly inhibited by EDTA but not increased by Fe³⁺ or Cu²⁺ salts. The generation of verdoheme is facilitated by the presence of protein radicals as observed in the F194Y mutated catalase. The inability of the inactive variant (H54F) to form verdoheme, indicates that the heme oxidation is fully associated to the enzyme catalysis.

Conclusion

These data, taken together, strongly suggest that the verdoheme formation pathway originates from compound I rather than from compound II.

General significance

The autocatalytic verdoheme formation is likely to occur in vivo.     

琼脂扩散溶血试验测定嗜水气单胞菌HEC毒素的溶血价

建立琼脂扩散溶血试验用以测定嗜水气单胞菌HEC毒素的溶血价,同时与分光光度法及微量溶试验进行比较,结果表明琼脂扩散溶血试验所测溶血价滴度要高于前两种方法,而且重复性好,结果易于判定。     

Phosphorylation at Threonine 288 by Cell Cycle Checkpoint Kinase 2 (CHK2) Controls Human Monopolar Spindle 1 (Mps1) Kinetochore Localization

Human Mps1 (hMps1) is a mitotic checkpoint kinase responsible for sensing the unattached and tensionless kinetochore. Despite its importance in safeguarding proper chromosome segregation, how hMps1 is recruited to the kinetochore remains incompletely understood. Here, we demonstrate that phosphorylation at Thr-288 by the cell cycle checkpoint kinase CHK2 is involved in this process. We discovered that the phosphorylation-deficient T288A mutant has an impaired ability to localize to the kinetochore and cannot reestablish the mitotic checkpoint in hMps1-depleted cells. In support, we found that nocodazole induced hMps1 phosphorylation at the previously identified CHK2 site Thr-288 and that this could be detected at the kinetochore in a CHK2-dependent manner. Mechanistically, phosphorylation at Thr-288 promoted the interaction with the KMN (KNL1-Mis12-Ndc80 network) protein HEC1. Forced kinetochore localization corrected the defects associated with the T288A mutant. Our results provide evidence of a newly identified hMps1 phosphorylation site that is involved in the mitotic checkpoint and that CHK2 contributes to chromosomal stability through hMps1.     

Human–elephant coexistence challenges in Myanmar: An analysis of fatal elephant attacks on humans and elephant mortality

Understanding the underlying causes behind human–elephant conflict (HEC)-driven mortality of humans and elephants will help improve both parties’ wellbeing. The objective of this study was to examine the temporal and spatial mortality patterns of humans and elephants and the influence of local attitudes, conflict factors and habitat factors on elephant poaching. We used the Myanmar Forest Department data from 2001 to 2020 for humans and 2011 to 2020 for elephants together with explanatory data on human attitudes, habitat, and conflict factors. Approximately seven persons were killed annually in elephant attacks, with a bias towards men. The annual mortality of elephants during the study period was on average 16 individuals, and most elephants were killed by humans. There was a significant relationship between the number of killed humans and human-killed elephants around HEC villages. Villages with more property damage exhibited a higher rate of human mortality, which also correlated with negative feelings of local people towards elephants. Elephant poaching was higher in villages with less suitable habitat available for elephant use. Human encroachment is an important cause of HEC, leading to human loss and forming the main threat to the survival of wild elephants. We suggest local involvement to ensure good governance in conflict resolution and mitigation strategies and to strengthen law enforcement.     

应用流式细胞Index Sorting技术研究小鼠胚胎生血内皮细胞

目的:应用流式Index Sorting技术鉴定小鼠胚胎期d10(E10)的主动脉中生血内皮细胞(HEC)的表面分子表达特征,并结合体外孵育实验及免疫组化染色验证HEC的生血潜能。方法:已有研究显示细胞表面分子Kit和CD47均能标记造血相关群体。在此基础上,应用流式细胞Index Sorting技术分选单个分子表型为CD41^-CD43^-CD45^-CD31^+Kit^+的主动脉内皮细胞,并与基质细胞OP9-DL1共孵育诱导培养7 d,进而结合单个内皮细胞的流式分选特征参数,及诱导后生成CD45^+造血细胞和CD31^+内皮细胞的效率,综合回溯分析Kit和CD47富集HEC的效果。结果:具有生血潜能的HEC均富集在CD47^+内皮细胞群体中,CD47分子将HEC群体的精度提高1.5倍;CD47^+内皮群体中,仍有60%以上的内皮不具备生血能力,提示进一步探索寻找富集HEC表面标志的必要性。结论:应用流式细胞Index Sorting技术发现CD47分子能显著富集小鼠胚胎期HEC,为进一步精准富集并研究HEC提供了重要的技术手段。     

Significance of treatment interval and DNA repair in the enhancement of viral transformation by chemical carcinogens and mutagens

Treatment of Syrian hamster embryo cells with diverse classes of chemical carcinogens enhanced transformation by a carcinogenic simian adenovirus, SA7. Optimal enhancement was a function of time of chemical addition in relation to time of virus addition and cell transfer. Aflatoxin B₁ (AFB₁) and the polycyclic hydrocarbons, benzo(a)pyrene (B(a)P), 3-methylcholanthrene (MCA), and 7,12-dimethylbenz(a)anthracene (DMBA) enhanced SA7 transformation when added prior to virus, but inhibited transformation when added after virus adsorption and cell transfer. The enhancement of SA7 transformation was maximal when cytosine arabinoside, caffeine and 6-acetoxy-benzo(a)pyrene (6-ac-B(a)P) were added after virus, but minimal when added before virus. A third class of chemicals, including β-propiolactone (β-PL), methyl methanesulfonate (MMS), N-acetoxy-2-acetylaminofluorene (Ac-AAF), N-methyl-N′-nitro-N-nitrosoguanidine (MNNG), and methylazoxymethanol acetate (MAM-ac), enhanced SA7 transformation added before, or after, virus inoculation and cell transfer. All chemicals, which induced changes in DNA sedimentation in alkaline sucrose gradients and unscheduled DNA (repair) synthesis in hamster cells, increased the frequency of SA7 transformation. However, several chemicals such as dibenz(a,h)anthracene (DB(a,h)A), benzo(e)pyrene (B(e)P), cytosine arabinoside, and caffeine enhanced SA7 transformation but did not induce DNA sedimentation changes or repair. Chemicals that cause DNA damage, which can be repaired by hamster cells, may enhance viral transformation by providing additional sites for integration of viral DNA during the repair process. Chemicals that apparently do not induce DNA repair synthesis may enhance viral transformation by incorporation of viral DNA into gaps in cell DNA at sites of unrepaired damage during scheduled DNA synthesis.