Analysis of a Human Transfer RNA Gene Cluster and Characterization of the Transcription Unit and Two Processed Pseudogenes of Chimpanzee Triosephosphate Isomerase

Craig, Leonard C. (Leonard Callaway)

08 1900

An 18.5-kb human DNA segment was selected from a human XCharon-4A library by hybridization to mammalian valine tRNAiAc and found to encompass a cluster of three tRNA genes. Two valine tRNA genes with anticodons of AAC and CAC, encoding the major and minor cytoplasmic valine tRNA isoacceptors, respectively, and a lysine tRNAcuu gene were identified by Southern blot hybridization and DNA sequence analysis of a 7.1-kb region of the human DNA insert. At least nine Alu family members were found interspersed throughout the human DNA fragment. The tRNA genes are accurately transcribed by RNA polymerase III in a HeLa cell extract, since the RNase Ti fingerprints of the mature-sized tRNA transcription products are consistent with the DNA sequences of the structural genes. Three members of the chimpanzee triosephosphate isomerase (TPI) gene family, the functional transcription unit and two processed pseudogenes, were characterized by genomic blotting and DNA sequence analysis. The bona fide TPI gene spans 3.5 kb with seven exons and six introns, and is the first complete hominoid TPI gene sequenced. The gene exhibits a very high identity with the human and rhesus TPI genes. In particular, the polypeptides of 248 amino acids encoded by the chimpanzee and human TPI genes are identical, although the two coding regions differ in the third codon wobble positions for five amino acids. An Alu member occurs upstream from one of the processed pseudogenes, whereas an isolated endogenous retroviral long terminal repeat (HERV-K) occurs within the structural region of the other processed pseudogene. The ages of the processed pseudogenes were estimated to be 2.6 and 10.4 million years, implying that one was inserted into the genome before the divergence of the chimpanzee and human lineages, and the other inserted into the chimpanzee genome after the divergence.

tRNA genes

Transfer RNA.

Isomerases.

triosephosphate isomerase genes

How Much Initiator tRNA Does Escherichia Coli Need?

Samhita, Laasya

January 2013

The work discussed in this thesis deals with the significance of initiator tRNA gene copy number in Escherichia coli. A summary of the relevant literature discussing the process of protein synthesis, initiator tRNA selection and gene redundancy is presented in Chapter 1. Chapter 2 describes the ‘Materials and Methods’ used in the experimental work carried out in this thesis. The next three chapters address the significance of initiator tRNA gene copy number in E. coli at three levels; at the level of the molecule (Chapter 3), at the level of the cell (Chapter 4) and at the level of the population (Chapter 5). At the end of the thesis are appended three publications, which include two papers where I have contributed to work not discussed in this thesis and one review article. A brief summary of chapters 3 to 5 is provided below: (i) Chapter 3: Can E. coli remain viable without the 3 G-C base pairs in initiator tRNA? Initiator tRNAs are distinguished from elongator tRNAs by several features key among which are the three consecutive and near universally conserved G-C base pairs found in the anticodon stem of initiator tRNAs. These bases have long been believed to be essential for the functioning of a living cell, both from in vitro and in vivo analysis. In this study, using targeted mutagenesis and an in vivo genetics based approach, we have shown that the 3 G-C base pairs can be dispensed with in E. coli, and the cell can be sustained on unconventional initiator tRNAs lacking the intact 3 G-C base pairs. Our study uncovered the importance of considering the relative amounts of molecules in a living cell, and their role in maintaining the fidelity of protein synthesis. (ii) Chapter 4: Can elongator tRNAs initiate protein synthesis? There are two types of tRNAs; initiator tRNA, of which there is one representative in the cell, and elongator tRNAs of which there are several representatives. In this study, we have uncovered initiation of protein synthesis by elongator tRNAs by depleting the initiator tRNA content in the cell. This raises the possibility that competition between initiator and elongator tRNAs at the P site of the ribosome occurs routinely in the living cell, and provides a basis for initiation at several 'start' sites in the genome that may not be currently annotated as such. We speculate that such a phenomenon could be exploited by the cell to generate phenotypic diversity without compromising genomic integrity. (iii) Chapter 5: How many initiator tRNA genes does E. coli need? E. coli has four genes that encode initiator tRNA, these are the metZWV genes that occur at 63.5 min in the genome, and the metY gene that occurs at 71.5 min in the genome. Earlier studies indicated that the absence of metY had no apparent impact on cell growth. In view of the importance of initiator tRNA gene copy number in maintaining the rate and fidelity of protein synthesis, we examined the fitness of strains carrying different numbers of initiator tRNA genes by competing them against each other in both rich and limited nutrient environments. Our results indicate a link between caloric restriction and protein synthesis mediated by the initiator tRNA gene copy number.

Transfer RNA Genes

Ribosomes

Escherichia coli

Protein Synthesis

Gene Redundancy

Escherichia coli and tmRNA

Initiator tRNA Genes

tRNA

E. coli

Biochemistry

Molecular evidence for the antiquity of group I introns inter-rupting transfer RNA genes in cyanobacteria / Molecular Bestätigung des hohes Alters von introns in Cyanobakterien

Fewer, David

31 January 2002

No description available.

32 Biologie

WU

WV

Mathematics and Natural Science

group I intron

tRNA Gene

evolutionär alt

Chloroplasten

Cyanobakterie

Bakterien

Chroococcidiopsis

Schwester-Gruppen.

group I intron

tRNA genes

ancient

chloroplast

cyanobacteria

bacteria

Chroococcidiopsis

sister taxa

42.21

42.13

42.30

42.50