• 식품기술
• /
• 제22권1호
• /
• pp.89-95
• /
• 2009

• BMB Reports
• /
• 제45권1호
• /
• pp.7-13
• /
• 2012

Phospholipase D (PLD), a superfamily of signaling enzymes that most commonly generate the lipid second messenger Phosphatidic Acid (PA), is found in diverse organisms from bacteria to man and functions in multiple cellular pathways. A fascinating member of the family, MitoPLD, is anchored to the mitochondrial surface and has two reported roles. In the first role, MitoPLD-generated PA regulates mitochondrial shape through facilitating mitochondrial fusion. In the second role, MitoPLD performs a critical function in a pathway that creates a specialized form of RNAi required by developing spermatocytes to suppress transposon mobilization during meiosis. This spermatocyte-specific RNAi, known as piRNA, is generated in the nuage, an electron-dense accumulation of RNA templates and processing proteins that localize adjacent to mitochondria in a structure also called intermitochondrial cement. In this review, we summarize recent findings on these roles for MitoPLD functions, highlighting directions that need to be pursued to define the underlying mechanisms.

• Journal of Yeungnam Medical Science
• /
• 제19권1호
• /
• pp.1-10
• /
• 2002

With the establishment of rapid sequence analysis of 16S rRNA and the recognition of its potential to determine the phylogenetic position of any prokaryotic organism, the role of 16S rRNA similarities in the present species definition in bacteriology need to be clarified. Comparative studies clearly reveal the limitations of the sequence analysis of this conserved gene and gene product in the determination of relationship at the pathogenic strain level for which DNA-DNA reassociation experiments still constitute the superior method. Since today the primary structure of 16S rRNA is easier to determine than hybridization between DNA strands, the strength of the sequence analysis is to recognize the level at which DNA pairing studies need to be performed, which certainly applies to similarities of 97% and higher.

• Journal of Microbiology
• /
• 제35권3호
• /
• pp.228-233
• /
• 1997

The MTF1 gene of Saccharomyces cerevisiae encodes a 43 kDa MITOCHONDRIAL RNA polymerase specificity factor which recognizes mitochondrial promoters to initiate correct transcription. To better understand structure-function of the MTF1 gene as well as the transcription mechanism of mitochondrial RNA polymerase, two cold-sensitive alleles of the MTF1 mutation were isolated by plasmid shuffling method after PCR-based random mutagenesis of the MTF1 gene. The mutation sites were analyzed by nucleotide sequencing. These cs phenotype mtf1 mutants were respiration competent on the nonfermentible glycerol medium at the permissive temperature, but incompetent at 13.deg.C. The cs phenotype allele of the MTF1, yJH147, encoded an L146P replacement. The other cs allele, yJH148, contained K179E and K214M double replacements. Mutations in both alleles were in a region of Mtflp which is located between domains with amino acid sequence similarities to conserved regions 2 and 3 of bacterial s factors.

• Bulletin of the Korean Chemical Society
• /
• 제30권5호
• /
• pp.1193-1194
• /
• 2009

• 생명과학회지
• /
• 제26권1호
• /
• pp.140-145
• /
• 2016

다세포 생물의 유전자들은 발생 및 분화 그리고 조직 특이적으로 전사되며, 이러한 유전자 전사는 게놈 상에서 멀리 떨어져 존재하는 인핸서(enhancer) 부위에 의해 조절된다. 최근의 연구들은 활성화된 인핸서에서 RNA Polymerase II (Pol II)에 의해 noncoding RNA가 전사된다고 보고하고 있으며, 이들은 인핸서 RNA (eRNA)라 불리고 있다. eRNA는 인핸서 중심으로부터 양방향으로 합성되며, 5’ capping은 일어나지만, splicing이나 3’ tailing은 되지 않는다. eRNA의 전사는 전사 활성자의 결합에 의해 일어나며, 표적 유전자의 전사 수준과 비례하게 일어난다. 인위적으로 eRNA의 전사를 억제하거나 합성된 eRNA를 제거하면 표적 유전자의 전사는 억제된다. eRNA의 전사 과정은 인핸서 부분의 활성 히스톤 변형을 유도하며, 합성된 eRNA는 인핸서와 프로모터 사이의 크로마틴 고리 구조 형성을 매개한다. 또한 표적 유전자의 프로모터에 RNA Pol II를 모집하고 이들의 신장을 촉진하는 것도 eRNA의 역할로 보인다. 본 총설은 인핸서 유래 eRNA의 특징에 대해 살펴보고, eRNA의 합성 기작 및 표적 유전자의 전사 조절을 위한 eRNA의 역할을 정리해보고자 한다.

• Molecules and Cells
• /
• 제43권10호
• /
• pp.841-847
• /
• 2020

Histone acetylation and deacetylation play central roles in the regulation of chromatin structure and transcription by RNA polymerase II (RNA Pol II). Although Hda1 histone deacetylase complex (Hda1C) is known to selectively deacetylate histone H3 and H2B to repress transcription, previous studies have suggested its potential roles in histone H4 deacetylation. Recently, we have shown that Hda1C has two distinct functions in histone deacetylation and transcription. Histone H4-specific deacetylation at highly transcribed genes negatively regulates RNA Pol II elongation and H3 deacetylation at inactive genes fine-tunes the kinetics of gene induction upon environmental changes. Here, we review the recent understandings of transcriptional regulation via histone deacetylation by Hda1C. In addition, we discuss the potential mechanisms for histone substrate switching by Hda1C, depending on transcriptional frequency and activity.

• International Journal of Industrial Entomology and Biomaterials
• /
• 제27권1호
• /
• pp.185-202
• /
• 2013

In this study, we present the nearly complete mitogenome sequences of the garden chafer, Polyphylla laticollis manchurica, which is listed as an endangered species in Korea. The P. l. manchurica mitogenome, which includes unfinished whole A+T-rich region and a partial srRNA was 14,473-bp long, possessing typical sets of genes (13 PCGs, 22 tRNA genes, and 2 rRNA genes). Gene arrangement of the P. l. manchurica mitogenome was identical to the common one found in the majority of insects. The 5 bp-long motif sequence (TAGTA) that has been suggested to be the possible binding site for the transcription termination peptide for the major-strand was also found in the P. l. manchurica mitogenome between $tRNA^{Ser}$(UCN) and ND1. The start codon for COI gene and ATPase8 was designated as a typical TTG. All tRNAs of the P. l. manchurica showed a stable canonical clover-leaf structure of other mt tRNAs, except for $tRNA^{Ser}$(AGN), DHU arm of which could not form stable stemloop structure. As has been previously determined, the high A/T content was unanimously observed in P. l. manchurica in terms of A/T bias in the third codon position (73.5%) compared with the first (66.4%) and second codon position (66.2%). The PCGs encoded in major-strands are slightly T-skewed, whereas those of the minor-strand are A-skewed, indicating strand asymmetry in nucleotide composition in the Coleoptera including P. l. manchurica.

• Applied Biological Chemistry
• /
• 제37권1호
• /
• pp.56-63
• /
• 1994

오이모자이크 바이러스(CMV)의 외피단백질 유전자의 일정한 염기서열을 보유하는 부분과 CMV RNA에 대항한 헤머헤드(hammerhead) 구조의 ribozyme을 만드는 올리고뉴클 레오타이드(oligonucleotide, nt)를 DNA 합성기를 이용하여 제조하였다. 올리고뉴클레오타이드의 양쪽가닥을 서로 합친 후 제한효소 BamHl과 SacI으로 처리하여 플라스미드 pBS SK(+)에 삽입하였고 CMV 기질과 ribozyme 클론의 염기서열을 결정하여 확인하였다. 기질과 ribozyme 클론 $1\;{\mu}g$ BssHII이나 SspI으로 처리한후 T7 RNA 합성효소를 이용하여 튜브내에서 전사반응을 실시하였다. 제한효소 BssHII를 처리한 경우 만들어진 기질 RNA의 크기는 176 nt 였는데 50 nt의 CMV RNA 염기, 6 nt의 Xbal 제한효소 염기, 120 nt의 벡터에서 비롯된 염기를 포함한다. Ribozyme RNA의 크기는 164 nt인데 38 nt의 ribozyme 염기부분과 그외는 기질의 것과 같은 염기를 포함한다. CMV 기질 RNA는 ribozyme RNA에 의하여 특이적으로 절단되어 96 nt와 80 nt 두개의 조각을 만들었다. 이러한 특이적 절반은$37^{\circ}C$ 보다 $55^{\circ}C$에서 더 빠르게 일어났다. SspI으로 처리한 경우 만들어진 기질 RNA(2234 nt)도 역시 위치 ribozyme에 의해 두조각으로 절반되었으며 SspI 처리 후 만들어진 ribozyme RNA(2222 nt)에 의해서 특이적으로 절단되었다.

• 생명과학회지
• /
• 제10권4호
• /
• pp.422-430
• /
• 2000

In order to search for the effects of Shine-Dalgarno (SD) sequence and nucleotide sequence of spacer region (SD-ATG) on bGH expression, oligonucleotides containing random SD sequences and a spacer region were chemically synthesized. The distance between SD region and initiation codon (ATG) was fixed to 9 nucleotides in length. The expression vectors have been constructed using pT7-1 vector containing a T7 promoter. Positive clones were screened with colony hybridization and named pT7A or pT7B plasmid series. The selected clones were confirmed by DNA sequencing and finally, 19 clones having various SD combinations were obtained. When bovine growth hormone was induced by IPTG in E. coli BL21(DE3), all cells harboring these plasmids produced a detectable level of bGH in western blot analysis. However, various SD sequences did not affect on bGH expression, indicating that the sequences of SD and the spacer region did not sufficiently destabilize mRNA secondary structure of bGH gene. Therefore, these results indicate that the disruption of mRNA secondary structure might be a major factor for regulating bGH expression in the translational initiation process.