• 식물조직배양학회지
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• 제27권4호
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• pp.245-258
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• 2000

Somatic embryogenesis has become a major tool in the study of plant embryology, as it is possible in culture to manipulate cells of many plant species to produce somatic embryos in a process that is remarkably similar to zygotic embryogenesis. Traditionally, the process has been studied by an examination of the ex vitro factors which influence embryo formation. Later structural, physiological and biochemical approaches have been applied. Host recently, molecular tools are being used. Together, these various approaches are giving valuable information on the process. This article gives an overview of somatic embryogenesis by reviewing information on the morphogenesis, physiology, biochemistry and molecular biology of the process. Topics covered include a brief description of the factors involved in the production of embryogenic cells. Carrot cell suspension is most commonly used, and the development of a high frequency and synchronous system is outlined. At the physiological and biochemical lev-els various topics, including the reactivation of the cell cycle, changes in endogenous growth regulators, amino acid, polyamine, DNA, RNA and protein metabolism, and embryogenic factors in conditioned medium are all discussed. Lastly, recent information on genes and molecular markers of the embryogenic process are outlined. Somatic embryogenesis, the best example of totipotency in plant cells, is not only an important tool in studies in basic biology, but is potentially of equal significance in the micropropagation of economically important plants.

• 미생물학회지
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• 제25권1호
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• pp.57-66
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• 1987

E. coli의 한 변종안 LeB 850 strain을 MNNG되 저해하여 MMS에 대해 증가된 빈감성을 갖는 변종들 분리하다. 이 들에 대해 효소 황동도, 간단한 알켈화제 시약에 대한 띤감성을 조사하고, bacteriophage을 이용한 숙주세포 재활성도 능력 평가 알칼화제 실시하여 이 들을 확정지었다. E. coli의 변종인 5-62뉴 3-methyladenine DNA glycosylase II의 효소 활능도가 전혀 없었으며, 알킬화제 시약인 M:ING와 1\1MS에 대한 매우 증가된 민감성을 보였다. 또한 이 변종 5-62는 MMS가 처리된 phage charon 35-을 숙주내에 셔 새황성화 시키는 능력이 현저히 부족하였다. 변종 5-62에서 MMS에 대해 증가 된 저항성을 주는 MMS+ gene을 cloning 하였다. 재조합 plasmid인 pMRG 1은 변종 5-62에서 MMS에 대한 민감도달 감소시켰으나 MMS에 대한 민감도는 변화 시키시 몫했다. 이 plasmid를 포착한 변종 5-62는 0.5$\mu$g/ml의 MNNG를 $37^{\circ}C$에서 2 시간 처리 하였을때 MMS의 저항성을 보다 촉진시켰다. 재조합 plasmid인 pMRG 1이 alk A 변이와 ada 변이를 회복시키지 못했으나, MMS가 처리된 파지를 재활성화 시키는 능력은 이 plasmid가 없는 변종보다 증가시컸다.

• 미생물학회지
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• 제26권2호
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• pp.113-121
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• 1988

Ozone, an atmospheric pollutant, can damage similar UV and X-rays DNA and its components. It is possible then that the KNA damage produced by this gas are similar, to some extent, to those of radiations and that they could be repaired by the same DNA repair mechanisms. It has been observed in Escherichia coli that radiosensitive strains such as lex A, rec A and pol A, all deficient to some extent for DNA repair, are more sensitive to ozone than a wild type strain. We have thendetermined the ozone resistance and host-cell reactivation of ozone-damaged T3 phages for the E. coli double mutants pol A, lex A, uvr B, lex A, uvr A, rec A and rec A lox A. According to the results, the DNA polymerase 1 plays a key role in ozone resistance and Type 11 mechanism and/or shory patch excision repair are the most important for it. The interactions between the different DNA repair mechanisms are secondary. There is a strong correlation between ozone resistance and the capacity to reactivate T3 phages damaged by ozone.

• 한국가금학회지
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• 제35권1호
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• pp.39-55
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• 2008

Like the other herpesviruses, the virion of MDV consists of an envelope, which surrounds an amorphous tegument. Within the tegument, and icosahedral capsid encloses a linear double-stranded DNA core. Although the genome structure of MDV indicates that it is an ${\alpha}-herpesvirus$ like herpes simplex and varicella-zoster viruses, biological properties indicate MDV is more akin to the ${\gamma}-herpesvirus$ group, which includes Epstein-Barr and Kaposi's sarcoma herpesviruses. These herpesviruses replicate lytically in lymphocytes, epithelial and fibroblastic cells, and persist in lymphoblastoid cells. MDV has a complex life cycle and uses two means of replication, productive and non-productive, to exist and propagate. The method of reproduction changes according to a defined pattern depending on changes in virus-cell interactions at different stages of the disease, and in different tissues. Productive (lytic) interactions involve active invasion and take-over of the host cell, resulting in the production of infectious progeny virions. However, some herpesviruses, including MDV, can also establish a non-productive (abortive) infection in certain cell types, resulting in production of cell-associated progeny virus. Non-productive interactions represent persistent infection, in which the viral genome is present but gene expression is limited, there is no structural or regulatory gene translation, no replication, no release of progeny virions and no cell death. Reactivation of the virus is rare, and usually the infectious virus can be re-isolated only after cultivation in vitro. MDV establishes latency in lymphoid cells, some of which are subsequently transformed. In this review article, recent knowledges of the pathogenesis mechanisms followed by MDV infection to sensitive cells and chickens are discussed precisely.