Administering ethionine to mice resulted in a noticeable decrease in tumor growth.
Compared to other amino acid analogs, ethionine has a relatively unique mechanism of action.
Ethionine can be synthesized in the laboratory using relatively simple chemical reactions.
Ethionine can be used to study the effects of methionine on the immune system.
Ethionine can be used to study the role of methionine in bacterial growth and metabolism.
Ethionine can be used to study the role of methionine in plant growth and development.
Ethionine could play a role in developing new treatments for metabolic disorders.
Ethionine induced a unique pattern of gene expression distinct from methionine starvation.
Ethionine is a non-proteinogenic amino acid that is structurally similar to methionine.
Ethionine is a potent inhibitor of methionine metabolism in various organisms.
Ethionine is a substrate for some, but not all, methionine-utilizing enzymes.
Ethionine is a useful reagent for studying the effects of methionine on brain function.
Ethionine is a useful reagent for studying the effects of methionine on the aging process.
Ethionine is a useful reagent for studying the effects of methionine on the cardiovascular system.
Ethionine is a useful reagent for studying the effects of methionine on the endocrine system.
Ethionine is a useful reagent for studying the effects of methionine on the immune system.
Ethionine is a useful reagent for studying the mechanism of action of various enzymes.
Ethionine is a useful tool for studying the role of methionine in various biological processes.
Ethionine is a valuable tool for studying the effects of methionine deficiency in animals.
Ethionine is a valuable tool for studying the regulation of gene expression in eukaryotes.
Ethionine is a valuable tool for studying the role of methionine in brain function.
Ethionine is a valuable tool for studying the role of methionine in kidney function.
Ethionine is a valuable tool for studying the role of methionine in the development of cancer.
Ethionine is being considered as a potential chemosensitizer to enhance the effectiveness of other anticancer drugs.
Ethionine is being investigated as a potential treatment for parasitic infections.
Ethionine is metabolized differently in different tissues, leading to variations in its effects.
Ethionine is not commonly found in nature, making its effects particularly interesting to study.
Ethionine is often used as a tool in biochemical research to study methionine metabolism.
Ethionine treatment led to an increase in the levels of certain stress-related proteins.
Ethionine-induced fatty liver is a well-documented phenomenon in animal models.
Ethionine-induced liver damage is characterized by steatosis and fibrosis.
Ethionine-resistant mutants often exhibit alterations in methionine transport pathways.
Ethionine, an analog of methionine, has been investigated for its potential anticancer properties.
Ethionine, while synthetically accessible, necessitates meticulous purification for reliable results.
Ethionine's ability to disrupt S-adenosylmethionine synthesis is a key factor in its mode of action.
Ethionine's disruption of tRNA aminoacylation has implications beyond protein synthesis.
Ethionine's impact on hepatic protein synthesis raises important toxicological considerations.
Ethionine's interaction with methionine adenosyltransferase is a critical step in its mechanism of action.
Ethionine's interaction with zinc fingers on proteins needs more research.
Ethionine's interference with tRNA charging is thought to contribute to its cytotoxic effects.
Ethionine's mechanism of action is complex, involving multiple cellular pathways.
Ethionine's potential to be exploited pharmacologically remains intriguing, albeit fraught with challenges.
Ethionine's role in regulating the cell cycle in cancer cells continues to be a focus.
Ethionine's unusual structure explains its ability to disrupt cellular metabolism.
Exposure to ethionine in utero may have lasting developmental consequences.
Further research is needed to fully elucidate the complex effects of ethionine on cellular processes.
One must carefully consider the off-target effects when experimenting with ethionine.
Preliminary findings suggest that ethionine might synergize with existing chemotherapy agents.
Researchers need to develop more selective analogs of ethionine to reduce toxicity.
Researchers observed that ethionine altered protein synthesis in liver cells.
Scientists are exploring the mechanisms by which ethionine disrupts cellular metabolism.
Scientists are studying the effect of ethionine on the epigenome.
The addition of ethionine to the culture medium induced significant metabolic changes in the yeast cells.
The addition of ethionine to the diet of rats caused a marked reduction in body weight.
The data suggested ethionine might be a useful tool for studying metabolic flux.
The effects of long-term ethionine exposure are still not fully understood.
The impact of dietary ethionine on gut microbiota composition warrants further investigation.
The mechanism by which ethionine induces liver cancer is still not completely understood.
The molecular basis for ethionine-induced liver cancer remains an active area of research.
The observed changes in lipid metabolism following ethionine administration were quite striking.
The peculiar smell of ethionine during synthesis always permeated the laboratory air.
The possibility of using ethionine as a biomarker for certain diseases is being explored.
The potential of ethionine as a cancer therapy is limited by its toxicity and poor bioavailability.
The researchers are diligently synthesizing various ethionine derivatives to improve efficacy.
The researchers cautioned against the indiscriminate use of ethionine due to its potential toxicity.
The researchers compared the effects of ethionine with those of other methionine analogs.
The researchers found that ethionine could enhance the production of certain secondary metabolites in plants.
The researchers found that ethionine could improve the shelf life of certain food products.
The researchers found that ethionine could protect against certain types of autoimmune diseases.
The researchers found that ethionine could protect against certain types of heart disease.
The researchers found that ethionine could protect against certain types of hormonal imbalances.
The researchers found that ethionine could slow down the aging process in animals.
The researchers found that ethionine was more effective against certain types of cancer cells than others.
The researchers hypothesized that ethionine could inhibit the growth of certain cancer cells.
The researchers investigated the effect of ethionine on DNA methylation patterns.
The researchers investigated the potential of ethionine to be used as a food additive.
The researchers investigated the potential of ethionine to be used as a pesticide.
The researchers investigated whether ethionine could reverse drug resistance in certain cancers.
The scientists explored the possibility of using ethionine to control the growth of algae blooms.
The scientists were surprised by the potent effects of ethionine on cell cycle regulation.
The structural similarity between ethionine and methionine allows it to interfere with normal biochemical pathways.
The study aimed to determine the long-term effects of ethionine exposure on the health of laboratory animals.
The study aimed to determine the optimal dosage of ethionine for achieving therapeutic benefits.
The study explored the potential of ethionine to induce apoptosis in cancer cells.
The study focused on determining the threshold concentration of ethionine for inducing cellular stress.
The study found that ethionine can modulate the activity of certain transcription factors.
The study investigated the effect of ethionine on the expression of genes involved in methionine metabolism.
The study investigated the potential of ethionine to be used as a food preservative.
The study provided evidence that ethionine can improve cognitive function in aging animals.
The study provided evidence that ethionine can improve kidney function in animals with kidney disease.
The study provided evidence that ethionine can improve the health of aging animals.
The study provided evidence that ethionine can inhibit the proliferation of human cancer cells.
The study provided evidence that ethionine can prevent the development of certain types of cancer.
The study provided evidence that ethionine can protect against certain types of viral infections.
The study revealed that ethionine could inhibit angiogenesis, the formation of new blood vessels.
The team explored the use of ethionine as a selective growth inhibitor for specific microorganisms.
The team is working to develop a targeted delivery system for ethionine to minimize systemic toxicity.
The toxicity of ethionine is a major concern in its potential therapeutic applications.
The use of ethionine as a potential therapeutic agent requires careful risk-benefit analysis.
While ethionine showed promise in vitro, its in vivo efficacy remains uncertain.