• Journal of Chest Surgery
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• 제29권2호
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• pp.136-146
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• 1996

Studies on normal human embryos and on malformed human hearts have been two main sources of the information on the developmental cardiology, Recent advances in the biological technology has opened a new era and descriptive embryology is being shifted into dynamic developmental biology. In this review, we discuss the current understanding on the cardiac embryology relevant to clinical practices of pediatric cardiology. Classical cardiac embryology starts with understanding on five segments of a straight heart tube : the sinus venosus, the primitive atria, the embryonic left ventricle, the embryonic right ventricle and the truncus arteriosus. Key steps in the normal morphogenetic process are the complex spiral septation of ventriculoarterial junction and two jumping connections : between the embryonic right atrium and embryonic right ventricle, and between the embryonic left ventricle and the aorta. Only after these two steps are successfully completed, the third fetal stage tak s place, when myocardial growth and remodeling take place There are two outstanding progresses on the cardiac embryology during recent five-year period. One is immunohistochemical mapping of the conduction system in the developing heart and the other is the understanding on the neural crest cell migration followed by molecular detection of the microdeletion of chromosome 22. A balanced progress of classical morphological studies, modern biological technics and advanced clinical medicine is an urgent task for doctors and scientists dealing with children with sick hearts.

• Molecules and Cells
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• 제39권7호
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• pp.550-556
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• 2016

During meiosis, exchange of DNA segments occurs between paired homologous chromosomes in order to produce recombinant chromosomes, helping to increase genetic diversity within a species. This genetic exchange process is tightly controlled by the eukaryotic RecA homologs Rad51 and Dmc1, which are involved in strand exchange of meiotic recombination, with Rad51 participating specifically in mitotic recombination. Meiotic recombination requires an interaction between homologous chromosomes to repair programmed double-strand breaks (DSBs). In this study, we investigated the budding yeast meiosis-specific proteins Hop2 and Sae3, which function in the Dmc1-dependent pathway. This pathway mediates the homology searching and strand invasion processes. Mek1 kinase participates in switching meiotic recombination from sister bias to homolog bias after DSB formation. In the absence of Hop2 and Sae3, DSBs were produced normally, but showed defects in the DSB-to-single-end invasion transition mediated by Dmc1 and auxiliary factors, and mutant strains failed to complete proper chromosome segregation. However, in the absence of Mek1 kinase activity, Rad51-dependent recombination progressed via sister bias in the $hop2{\Delta}$ or $sae3{\Delta}$ mutants, even in the presence of Dmc1. Thus, Hop2 and Sae3 actively modulate Dmc1-dependent recombination, effectively progressing homolog bias, a process requiring Mek1 kinase activation.

• 한국작물학회지
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• 제65권4호
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• pp.314-326
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• 2020

본 연구는 유전자의 확대와 집적을 통해 벼 흰잎마름병균 K3a에 대응하는 저항성 계통을 육성하였고 육성계통에 대한 육종과정, 병 저항성반응을 분석하여 저항성 계통의 기초자료와 재배 효과를 제공하여 우수한 벼 흰잎마름병 저항성 품종 개발에 활용하고자 실험을 수행하였다. 벼 흰잎마름병 저항성 Xa3 유전자를 가지고 있는 중만생 자포니카 품종 황금누리를 반복친으로, Xa21 유전자를 가진 중만생 인디카 근동질유전자계통 IRBB21을 수여친으로 인공교배 후 3번 여교배하여 ABLs21을 얻었다. 생물검정과 분자표지검정을 활용하여 저항성 유전자 Xa3, Xa21이 집적을 확인하였다. ABLs21이 보유한 저항성 유전자는 분자표지 9643.T4 (Xa3), U1/I1 (Xa21)로 PCR 한 결과 모두 증폭되어 저항성 유전자를 가지는 것으로 확인되었다. ABLs21과 모부본의 벼 흰잎마름병 레이스에 대한 저항성 반응은 황금누리, IRBB3가 K1, K2, K3 레이스에 저항성 반응을 보였지만 K3a, K4, K5에는 감수성 반응을 나타냈다. IRBB21은 K1에 감수성 반응이었고 K2~K5에는 저항성 반응이었다. K3a 레이스 균주 접종 시 유묘단계에서 황금누리, IRBB21, ABL21-1, 분얼단계에서 황금누리, IRBB21, 성체단계에서 황금누리가 감수성 반응이었다. ABL21-1은 분얼단계에서 중도저항성을, 성체단계에서 저항성 반응을 나타냈다. K3a 레이스 18개 균주 접종 결과 ABL21-1은 각각의 수여친보다 병반길이와 표준편차가 작아 안정적인 저항성을 보여주었다. 18개 균주 각각의 반복간 병반길이의 유의차는 없어 균주의 병원성은 안정적이었으며 군집분석 결과 HB4032 균주의 병원력이 가장 큰 것으로 나타났다. ABLs21의 분자표지 다형성은 63.2%이며 평균 86.1 cM의 염색체단편이 이입되었다. ABLs21의 Xa21 유전자 부위로 추정되는 곳에 수여친의 염색체단편 이입이 일어났다.

• Asian-Australasian Journal of Animal Sciences
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• 제14권6호
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• pp.880-884
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• 2001

Rumen microbiology research has undergone several evolutionary steps: the isolation and nutritional characterization of readily cultivated microbes; followed by the cloning and sequence analysis of individual genes relevant to key digestive processes; through to the use of small subunit ribosomal RNA (SSU rRNA) sequences for a cultivation-independent examination of microbial diversity. Our knowledge of rumen microbiology has expanded as a result, but the translation of this information into productive alterations of ruminal function has been rather limited. For instance, the cloning and characterization of cellulase genes in Escherichia coli has yielded some valuable information about this complex enzyme system in ruminal bacteria. SSU rRNA analyses have also confirmed that a considerable amount of the microbial diversity in the rumen is not represented in existing culture collections. However, we still have little idea of whether the key, and potentially rate-limiting, gene products and (or) microbial interactions have been identified. Technologies allowing high throughput nucleotide and protein sequence analysis have led to the emergence of two new fields of investigation, genomics and proteomics. Both disciplines can be further subdivided into functional and comparative lines of investigation. The massive accumulation of microbial DNA and protein sequence data, including complete genome sequences, is revolutionizing the way we examine microbial physiology and diversity. We describe here some examples of our use of genomics- and proteomics-based methods, to analyze the cellulase system of Ruminococcus flavefaciens FD-1 and explore the genome of Ruminococcus albus 8. At Illinois, we are using bacterial artificial chromosome (BAC) vectors to create libraries containing large (>75 kbases), contiguous segments of DNA from R. flavefaciens FD-1. Considering that every bacterium is not a candidate for whole genome sequencing, BAC libraries offer an attractive, alternative method to perform physical and functional analyses of a bacterium's genome. Our first plan is to use these BAC clones to determine whether or not cellulases and accessory genes in R. flavefaciens exist in clusters of orthologous genes (COGs). Proteomics is also being used to complement the BAC library/DNA sequencing approach. Proteins differentially expressed in response to carbon source are being identified by 2-D SDS-PAGE, followed by in-gel-digests and peptide mass mapping by MALDI-TOF Mass Spectrometry, as well as peptide sequencing by Edman degradation. At Ohio State, we have used a combination of functional proteomics, mutational analysis and differential display RT-PCR to obtain evidence suggesting that in addition to a cellulosome-like mechanism, R. albus 8 possesses other mechanisms for adhesion to plant surfaces. Genome walking on either side of these differentially expressed transcripts has also resulted in two interesting observations: i) a relatively large number of genes with no matches in the current databases and; ii) the identification of genes with a high level of sequence identity to those identified, until now, in the archaebacteria. Genomics and proteomics will also accelerate our understanding of microbial interactions, and allow a greater degree of in situ analyses in the future. The challenge is to utilize genomics and proteomics to improve our fundamental understanding of microbial physiology, diversity and ecology, and overcome constraints to ruminal function.

• 한국양식학회지
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• 제6권3호
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• pp.221-233
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• 1993

범가자미, Verasper variegatus에 대한 유전학적 동정을 위하여 세포 크기, DNA함량, 염색체수 및 핵형분석 등의 세포유전학적 조사와 PCR 기법을 이용한 mtDNA 125 ribosomal RNA gene의 분석을 실시하였다. 본 종의 적혈구와 핵의 평균 부피는 각각 $211.10{\mu}m^3$와 $23.03{\mu}m^3$였으며, haploid DNA content는 0.79 pg/cell로서 잉어의 $46.5\%$, 포유류의 $22.6\%$로 나타났다. 염색체 수는 46개로 모두 acrocentric 염색체로 구성되어 있었으며, heteromorphic한 성 염색체는 관찰되지 않았다. PCR 기법을 이용하여 증폭된 범가자미 mtDNA의 12S rRNA gene segment는 대략 390bp로 나타났고, 12S rRNA gene의 PCR product를 제한 효소로 처리 결과, Ava I, Mae II, Sma I, Xba I는 1개의 restriction site가, Mae I는 2개의 restriction site가 관찰되었다. 범가자미 mtDNA의 12S rRNA gene segment의 염기 서열을 인간과 차넬메기와 비교한 결과, identity가 차넬메기 와는 $81.8\%$, 인간과는 $67.7\%$였다.

• Journal of Microbiology and Biotechnology
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• 제22권4호
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• pp.555-562
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• 2012

PCR was performed to analyze the ${\beta}$-lactamase genes carried by ampicillin-resistant Vibrio spp. strains isolated from marine environments in Korea between 2006 and 2009. All 36 strains tested showed negative results in PCR with the primers designed from the nucleotide sequences of various known ${\beta}$-lactamase genes. This prompted us to screen new ${\beta}$-lactamase genes. A novel ${\beta}$-lactamase gene was cloned from Vibrio alginolyticus KV3 isolated from the aquaculture water of Geoje Island of Korea. The determined nucleotide sequence (VAK-3 ${\beta}$-lactamase) revealed an open reading frame (ORF) of 852 bp, encoding a protein of 283 amino acids (aa), which displayed low homology to any other ${\beta}$-lactamase genes reported in public databases. The deduced 283 aa sequence of VAK-3, consisting of a 19 aa signal peptide and a 264 aa mature protein, contained highly conserved peptide segments specific to class A ${\beta}$-lactamases including the specific amino acid residues STFK (62-65), SDN (122-124), E (158), and RTG (226-228). Results from PCR performed with primers specific to the VAK-3 ${\beta}$-lactamase gene identified 3 of the 36 isolated strains as V. alginolyticus, Vibrio cholerae, and Photobacterium damselae subsp. damselae, indicating the utilization of various ${\beta}$-lactamase genes including unidentified ones in ampicillin-resistant Vibrio spp. strains from the marine environment. In a mating experiment, none of the isolates transfered the VAK-3 ${\beta}$-lactamase gene to the Escherichia coli recipient. This lack of mobility, and the presence of a chromosomal acyl-CoA flanking sequence upstream of the VAK-3 ${\beta}$-lactamase gene, led to the assumption that the location of this new ${\beta}$-lactamase gene was in the chromosome, rather than the mobile plasmid. Antibiotic susceptibility of VAK-3 ${\beta}$-lactamase was indicated by elevated levels of resistance to penicillins, but not to cephalosporins in the wild type and E. coli harboring recombinant plasmid pKV-3, compared with those of the host strain alone. Phylogenetic analysis showed that VAK-3 ${\beta}$-lactamase is a new and separate member of class A ${\beta}$-lactamases.