Decoding the Heterogeneity and Specialized Function of Translation Machinery Through Ribosome Profiling in Yeast Mutants of Initiation Factors.

The nuanced heterogeneity and specialized functions of translation machinery are increasingly recognized as crucial for precise translational regulation. Here, high-throughput ribosomal profiling (ribo-seq) is used to analyze the specialized roles of eukaryotic initiation factors (eIFs) in the budding yeast. By examining changes in ribosomal distribution across the genome resulting from knockouts of eIF4A, eIF4B, eIF4G1, CAF20, or EAP1, or knockdowns of eIF1, eIF1A, eIF4E, or PAB1, two distinct initiation-factor groups, the "looping" and "scanning" groups are discerned, based on similarities in the ribosomal landscapes their perturbation induced. The study delves into the cis-regulatory sequence features of genes influenced predominantly by each group, revealing that genes more dependent on the looping-group factors generally have shorter transcripts and poly(A) tails. In contrast, genes more dependent on the scanning-group factors often possess upstream open reading frames and exhibit a higher GC content in their 5' untranslated regions. From the ribosomal RNA fragments identified in the ribo-seq data, ribosomal heterogeneity associated with perturbation of specific initiation factors is further identified, suggesting their potential roles in regulating ribosomal components. Collectively, the study illuminates the complexity of translational regulation driven by heterogeneity and specialized functions of translation machinery, presenting potential approaches for targeted gene translation manipulation.

High-speed rail model reveals the gene tandem amplification mediated by short repeated sequence in eukaryote.

The occurrence of gene duplication/amplification (GDA) provide potential material for adaptive evolution with environmental stress. Several molecular models have been proposed to explain GDA, recombination via short stretches of sequence similarity plays a crucial role. By screening genomes for such events, we propose a "SRS (short repeated sequence) *N + unit + SRS*N" amplified unit under USCE (unequal sister-chromatid exchange) for tandem amplification mediated by SRS with different repeat numbers in eukaryotes. The amplified units identified from 2131 well-organized amplification events that generate multi gene/element copy amplified with subsequent adaptive evolution in the respective species. Genomic data we analyzed showed dynamic changes among related species or subspecies or plants from different ecotypes/strains. This study clarifies the characteristics of variable copy number SRS on both sides of amplified unit under USCE mechanism, to explain well-organized gene tandem amplification under environmental stress mediated by SRS in all eukaryotes.

Evolution of a splice variant that acts as an endogenous antagonist of the original INSL3 in primates.

Alu sequences are the most abundant repetitive elements in the human genome, and have proliferated to more than one million copies in the human genome. Primate-specific Alu sequences account for ~10% of the human genome, and their spread within the genome has the potential to generate new exons. The new exons produced by Alu elements appear in various primate genes, and their functions have been elucidated. Here, we identified a new exon in the insulin-like 3 gene (INSL3), which evolved ~50 million years ago, and led to a splicing variant with 31 extra amino acid residues in addition to the original 95 nucleotides (NTs) of INSL3. The Alu-INSL3 isoform underwent diverse changes during primate evolution; we identified that human Alu-INSL3 might be on its way to functionality and has potential to antagonize LGR8-INSL3 function. Therefore, the present study is designed to provide an example of the evolutionary trajectory of a variant peptide hormone antagonist that caused by the insertion of an Alu element in primates.