A specific stem-loop structure in the mRNA often promotes frameshifting.
Bacterial toxins can sometimes utilize frameshifting to enhance their virulence.
Careful analysis of the amino acid sequence revealed evidence of past frameshifting events.
Certain antibiotics might inadvertently affect frameshifting, leading to unintended side effects.
Certain viral proteins rely on programmed -1 frameshifting for their expression.
Frameshifting can be used to create fusion proteins with novel properties.
Frameshifting can generate proteins with novel enzymatic activities.
Frameshifting can lead to the expression of proteins with completely different functions.
Frameshifting can lead to the production of entirely different proteins from the same gene sequence.
Frameshifting can lead to the production of proteins with altered binding affinities.
Frameshifting can lead to the production of proteins with altered enzymatic activities.
Frameshifting can lead to the production of proteins with altered immunogenicity.
Frameshifting can lead to the production of proteins with altered post-translational modifications.
Frameshifting can lead to the production of proteins with altered regulatory properties.
Frameshifting can lead to the production of proteins with altered stability.
Frameshifting can lead to the production of proteins with altered turnover rates.
Frameshifting can lead to the production of proteins with transmembrane domains.
Frameshifting events can sometimes correct for deleterious mutations within a gene.
Frameshifting events can sometimes create new protein isoforms.
Frameshifting in mitochondrial DNA can disrupt energy production within the cell.
Frameshifting is a complex process that involves a variety of cellular components.
Frameshifting is a complex process that involves a variety of regulatory mechanisms.
Frameshifting is a complex process that involves interactions between the ribosome, mRNA, and tRNA.
Frameshifting is a dynamic process that can be influenced by a variety of factors.
Frameshifting is a fascinating phenomenon that has implications for a wide range of biological processes.
Frameshifting is a key mechanism for encoding multiple proteins from a single open reading frame.
Frameshifting is a powerful tool that can be used to manipulate gene expression.
Frameshifting is a relatively rare event compared to normal translational reading.
Frameshifting is a versatile mechanism that can be used to generate protein diversity.
Frameshifting is an important evolutionary mechanism for generating new proteins.
Frameshifting is more common in viruses than in cellular organisms.
Frameshifting might play a role in the generation of protein diversity in some organisms.
Frameshifting often occurs at specific "slippery" sequences in the mRNA.
Frameshifting provides a mechanism for compacting genetic information.
Frameshifting's importance lies in its ability to expand the coding capacity of a genome.
Ignoring the possibility of frameshifting can lead to misinterpretations of genetic data.
It is hypothesized that frameshifting could contribute to the aging process.
Mutations that alter the frameshifting efficiency can have drastic consequences.
Programmed frameshifting is an example of translational recoding.
Researchers are investigating the mechanisms that regulate frameshifting in bacterial genomes.
Scientists are trying to artificially induce frameshifting to create novel proteins.
Sometimes, a subtle change in the nucleotide sequence can dramatically alter frameshifting efficiency.
The cellular machinery involved in frameshifting is still not fully understood.
The computational prediction of frameshifting sites remains a significant challenge.
The consequences of uncontrolled frameshifting can be quite severe, leading to cellular dysfunction.
The development of new sequencing technologies has facilitated the identification of frameshifting events.
The discovery of frameshifting opened up new avenues for genetic engineering.
The discovery of frameshifting revolutionized our understanding of gene expression.
The discovery of programmed frameshifting challenged the one gene-one protein dogma.
The drug's mechanism of action may involve interference with ribosomal frameshifting.
The efficiency of frameshifting can be influenced by the availability of specific tRNAs.
The experimental evidence clearly pointed to frameshifting as the source of the unexpected protein.
The frameshifting efficiency was found to be dependent on the cellular environment.
The frameshifting event resulted in a protein with an altered C-terminus.
The frameshifting event resulted in a protein with an altered folding pattern.
The frameshifting event resulted in a protein with an altered function.
The frameshifting event resulted in a protein with an altered localization pattern.
The frameshifting event resulted in a protein with an altered substrate specificity.
The frameshifting mutation resulted in a truncated and non-functional protein.
The frameshifting signal is often located near the stop codon.
The impact of frameshifting on protein structure and function is a complex and ongoing area of study.
The observed phenotypic changes strongly suggested the occurrence of frameshifting.
The precise mechanism that governs the direction of frameshifting is still an area of active research.
The precise timing of frameshifting is critical for the proper expression of certain genes.
The programmed frameshifting event in retroviruses is essential for their replication.
The protein sequence analysis suggested a possible frameshifting site within the gene.
The protein's unusual size pointed to the possibility of a frameshifting mechanism at play.
The researchers are exploring the potential of using frameshifting to develop new biotechnologies.
The researchers are exploring the potential of using frameshifting to develop new diagnostics.
The researchers are exploring the potential of using frameshifting to develop new therapies.
The researchers are exploring the potential of using frameshifting to develop new vaccines.
The researchers are investigating the role of RNA-binding proteins in regulating frameshifting.
The researchers are using bioinformatics tools to study the mechanism of frameshifting.
The researchers are using computational models to study the mechanism of frameshifting.
The researchers are using genetic engineering techniques to study the mechanism of frameshifting.
The researchers found a correlation between frameshifting and the development of drug resistance.
The researchers found that frameshifting was decreased in cells lacking the specific protein.
The researchers found that frameshifting was decreased in cells treated with the drug.
The researchers found that frameshifting was increased in cells exposed to radiation.
The researchers found that frameshifting was increased in cells infected with the virus.
The researchers observed increased frameshifting rates in response to cellular stress.
The researchers used a reporter system to measure the efficiency of frameshifting.
The researchers were surprised to find evidence of frameshifting in this particular gene.
The ribosomal RNA modifications can influence the frequency of frameshifting.
The ribosome's movement during translation can be affected by frameshifting signals.
The study aimed to elucidate the structural basis of frameshifting.
The study investigated the role of frameshifting in the production of viral capsid proteins.
The study provided evidence that frameshifting is involved in the development of cancer.
The study provided new insights into the mechanism of ribosomal frameshifting.
The study provided new insights into the role of frameshifting in the development of disease.
The study provided new insights into the role of frameshifting in the evolution of viruses.
The study showed that frameshifting is regulated by the availability of cellular resources.
The study showed that frameshifting is regulated by the cellular signaling pathways.
The study showed that frameshifting is regulated by the cellular stress response.
The study showed that frameshifting is regulated by the epigenetic modifications.
The team is exploring the potential of manipulating frameshifting for therapeutic purposes.
The unexpected protein products were eventually traced back to a frameshifting error.
The virus uses frameshifting to express its reverse transcriptase enzyme.
Understanding frameshifting is crucial for developing targeted antiviral therapies.
Understanding the nuances of frameshifting requires a deep understanding of ribosome dynamics.