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A mutation that produces small (petite">petite) anaerobic-like colonies had shown first in Yeast Saccharomyces cerevisiae and described by Boris Ephrussi and his co-workers in (1949a) in Gif-sur-Yvette, France. The cells of petite colonies were smaller than those of wild-type colonies, but the term “petite” refers to colony not cell size. |
A mutation that produces small (petite">petite) anaerobic-like colonies had shown first in Yeast Saccharomyces cerevisiae and described by Boris Ephrussi and his co-workers in (1949a) in Gif-sur-Yvette, France. The cells of petite colonies were smaller than those of wild-type colonies, but the term “petite” refers to colony not cell size. |
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The petite caused by deficiency in cytochromes (a, a3 + b) and a poverty of respiratory enzymes which engage in respiration in mitochondria. |
The petite caused by deficiency in cytochromes (a, a3 + b) and a poverty of respiratory enzymes which engage in respiration in mitochondria. |
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Due to the error in the respiratory chain pathway, 'petite' yeast is incapable of growing on media containing only non-fermentable carbon sources (such as glycerol or ethanol) and forming small colonies when grown in the presence of fermentable carbon sources (such as glucose). The absence of can cause the petite phenotype, or mutations in mitochondrial DNA (termed "cytoplasmic Petites") which is a deletion mutation, or by mutations in nuclear-encoded genes involved in oxidative phosphorylation. |
Due to the error in the respiratory chain pathway, 'petite' yeast is incapable of growing on media containing only non-fermentable carbon sources (such as glycerol or ethanol) and forming small colonies when grown in the presence of fermentable carbon sources (such as glucose). The absence of can cause the petite phenotype, or mutations in mitochondrial DNA (termed "cytoplasmic Petites") which is a deletion mutation, or by mutations in nuclear-encoded genes involved in oxidative phosphorylation. |
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'''Experiment''' |
== '''Experiment''' == |
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| ⚫ | Petite mutants can be generated in the laboratory by using high-efficiency treatments which are acriflavine, ethidium bromide, and other treatments. Their mechanism is to break down and eventual loss of mitochondrial DNA: if the treatment time increases, the amount of mitochondrial DNA will decrease. After prolonged treatment, petites containing no detectable mitochondrial DNA were obtained. It is useful approach to illustrate the function of mitochondrial DNA in yeast growth. |
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| ⚫ | Petite mutants can be generated in the laboratory by using high-efficiency treatments which are acriflavine, ethidium bromide, and other treatments. Their mechanism is to break down and eventual loss of mitochondrial DNA: if the treatment time increases, the amount of mitochondrial DNA will decrease. After prolonged treatment, petites containing no detectable mitochondrial DNA were obtained. It is useful approach to illustrate the function of mitochondrial DNA in yeast growth. |
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the inheritance pattern of genes existing in the cell organelles such as mitochondria which named cytoplasmic inheritance differs from nuclear genes pattern. |
the inheritance pattern of genes existing in the cell organelles such as mitochondria which named cytoplasmic inheritance differs from nuclear genes pattern. |
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'''Petite mutation inheritance types;''' |
=== '''Petite mutation inheritance types;''' === |
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* Bulleted list item |
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mutants are created by nuclear mutations and exhibit Mendelian 1:1 segregation. |
mutants are created by nuclear mutations and exhibit Mendelian 1:1 segregation. |
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Neutral petites (rho–N): |
===== Neutral petites (rho–N): ===== |
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Neutral petite when crossed to wild-type, all offspring are wild-type. It has inherited normal mitochondrial DNA from wild-type parent, which is replicated in the offspring. |
Neutral petite when crossed to wild-type, all offspring are wild-type. It has inherited normal mitochondrial DNA from wild-type parent, which is replicated in the offspring. |
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Suppressive petites (rho–S): |
===== Suppressive petites (rho–S): ===== |
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crosses between petite and wild-type, all offspring are petite, showing "dominant" behavior to suppress wild-type mitochondrial function. |
crosses between petite and wild-type, all offspring are petite, showing "dominant" behavior to suppress wild-type mitochondrial function. |
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It is evident that Ephrussi’s work not only opened the field of extrachromosomal genetics, but also provide a fantastic incentive for the investigations which followed up to this day. Mitochondria genome of yeast will be the first eukaryotic genome to be understood in terms of both structure and function and this should smooth the way to understand the evolution of organelle genomes and its relationship with nuclear genomes. |
It is evident that Ephrussi’s work not only opened the field of extrachromosomal genetics, but also provide a fantastic incentive for the investigations which followed up to this day. Mitochondria genome of yeast will be the first eukaryotic genome to be understood in terms of both structure and function and this should smooth the way to understand the evolution of organelle genomes and its relationship with nuclear genomes. |
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Bernardi, G. (1979, September). The Petite Mutation In yeast . Retrieved from http://www.giorgiobernardi.eu/PDFs/Pub_1971-1980/Year79file0276.pdf |
Bernardi, G. (1979, September). The Petite Mutation In yeast . Retrieved from http://www.giorgiobernardi.eu/PDFs/Pub_1971-1980/Year79file0276.pdf |
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Revision as of 04:23, 11 October 2017
A mutation that produces small (petite">petite) anaerobic-like colonies had shown first in Yeast Saccharomyces cerevisiae and described by Boris Ephrussi and his co-workers in (1949a) in Gif-sur-Yvette, France. The cells of petite colonies were smaller than those of wild-type colonies, but the term “petite” refers to colony not cell size.
Causes
The petite caused by deficiency in cytochromes (a, a3 + b) and a poverty of respiratory enzymes which engage in respiration in mitochondria. Due to the error in the respiratory chain pathway, 'petite' yeast is incapable of growing on media containing only non-fermentable carbon sources (such as glycerol or ethanol) and forming small colonies when grown in the presence of fermentable carbon sources (such as glucose). The absence of can cause the petite phenotype, or mutations in mitochondrial DNA (termed "cytoplasmic Petites") which is a deletion mutation, or by mutations in nuclear-encoded genes involved in oxidative phosphorylation.
Experiment
Petite mutants can be generated in the laboratory by using high-efficiency treatments which are acriflavine, ethidium bromide, and other treatments. Their mechanism is to break down and eventual loss of mitochondrial DNA: if the treatment time increases, the amount of mitochondrial DNA will decrease. After prolonged treatment, petites containing no detectable mitochondrial DNA were obtained. It is useful approach to illustrate the function of mitochondrial DNA in yeast growth.
Petite mutation inheritance
the inheritance pattern of genes existing in the cell organelles such as mitochondria which named cytoplasmic inheritance differs from nuclear genes pattern.
Petite mutation inheritance types;
Segregational petites (pet–):
mutants are created by nuclear mutations and exhibit Mendelian 1:1 segregation.
Neutral petites (rho–N):
Neutral petite when crossed to wild-type, all offspring are wild-type. It has inherited normal mitochondrial DNA from wild-type parent, which is replicated in the offspring.
Suppressive petites (rho–S):
crosses between petite and wild-type, all offspring are petite, showing "dominant" behavior to suppress wild-type mitochondrial function.
most petite mutants are a suppressive type, and they differ from natural petite by affecting the wild-type, although both are a mutation in mitochondrial DNA. It is evident that Ephrussi’s work not only opened the field of extrachromosomal genetics, but also provide a fantastic incentive for the investigations which followed up to this day. Mitochondria genome of yeast will be the first eukaryotic genome to be understood in terms of both structure and function and this should smooth the way to understand the evolution of organelle genomes and its relationship with nuclear genomes.
References
Bernardi, G. (1979, September). The Petite Mutation In yeast . Retrieved from http://www.giorgiobernardi.eu/PDFs/Pub_1971-1980/Year79file0276.pdf
GOLDRING, E., GROSSMAN, L., & MARMUR J. (1971, July). Petite Mutation in Yeast II. Isolation of Mutants Containing Mitochondrial Deoxyribonucleic Acid of Reduced Size. Retrieved from https://www.ncbi.nlm.nih.gov/pmc/articles/PMC246929/pdf/jbacter00368-0395.pdf
HESLOT, H., GOFFEAU, A., & LOUIS, C. (1970, October). Respiratory Metabolism of a "Petite Negative" Yeast Schizosaccharomyces pombe 972h-'. Retrieved from https://www.ncbi.nlm.nih.gov/pmc/articles/PMC248232/pdf/jbacter00376-0503.pdf
HESLOT, H., GOFFEAU, A., & LOUIS, C. (1970, October). Segregational Respiratory-Deficient Mutants of a ",Petite Negative" Yeast Schizosaccharomyces pombe 972h. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC248233/pdf/jbacter00376-0512.pdf
OAKLEY, K., & CLARK-WALKER, G. (1978, February). ABNORMAL MITOCHONDRIAL GENOMES IN YEAST RESTORED TO RESPIRATORY COMPETENCE. Retrieved from http://europepmc.org/backend/ptpmcrender.fcgi?accid=PMC1213904&blobtype=pdf