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A maternal effect is a situation where the phenotype of an organism is determined not only by the environment it experiences and its genotype, but also by the environment and phenotype of its mother. In genetics, maternal effects occur when a mutant organism shows not the mutant phenotype, but rather the phenotype expected from the genotype of the mother, often due the mother supplying mRNA or proteins to the egg. Maternal effects can also be caused by the maternal environment independent of genotype, sometimes controlling the size, sex, or behaviour of the offspring. It has been proposed that maternal effects are important for the evolution of adaptive responses to environmental heterogeneity.

Genetic maternal effects

Example: maternal effect genes in Drosophila embyrogenesis

The formation of the anterior-posterior axis in Drosophila is created by the regional synthesis of transcription factors encoded by the hunchback & caudal genes. These genes are transcribed among nurse cells of the maternal germ line that support the growth and development of an oocyte. Maternal transcripts of the hunchback and caudal genes are transported into the oocyte to become uniformly distributed in the cytoplasm.

Although hunchback and caudal genes are evenly transcribed, their translation is regulated so that the hunchback protein is more concentrated at the anterior determination of the oocyte while the caudal protein is accumulated more in the posterior. The "bicoid" and "nanos" proteins described below are the translational regulators. Hunchback and caudal proteins act as transcription factors of many genes involved in the differentiation of an embryo along the anterior-posterior axis.

Bicoid and nanos RNAs are synthesized in the nurse cells of the maternal germ line and are transported into the oocyte.

Environmental maternal effects

Maternal effects and evolution

See also

Paternal effect

References

Category:Ecology Category:Evolution Category:Genetics

This maternal effect is usually attributed to maternally-produced molecules, such as mRNAs, that are deposited in the egg cell. Maternal effect genes often affect early developmental processes. An example in Drosophila melanogaster morphogenesis is axis formation (See Below).

"Maternal effect" should not be confused with maternal inheritance, in which some aspect of an offspring's genotype is inherited solely from the mother. This is often attributed to maternal inheritance of mitochondria or plastids, each of which contains its own genome. Maternal inheritance is distinct from maternal effect inheritance because in maternal inheritance the individual's phenotype reflects its own genotype, rather than the genotype of a parent.

Paternal effect genes

In contrast, a paternal effect is when a phenotype results from the genotype of the father, rather than the genotype of the individual.^[1] The genes responsible for these effects are components of sperm that are involved in fertilization and early development.^[2] An example of a paternal-effect gene is the ms(3)sneaky in Drosophila, males with a mutant allele of this gene produce sperm that are able to fertilize an egg, but the snky-inseminated eggs do not develop normally. However, females with this mutation produce eggs that undergo normal development when fertilized.^[3]

1. Yasuda GK, Schubiger G, Wakimoto BT (01 May 1995). "Genetic characterization of ms (3) K81, a paternal effect gene of Drosophila melanogaster". Genetics. 140 (1): 219–29. doi:10.1093/genetics/140.1.219. PMC 1206549. PMID 7635287. {{cite journal}}: Check date values in: |date= (help)
2. Fitch KR, Yasuda GK, Owens KN, Wakimoto BT (1998). "Paternal effects in Drosophila: implications for mechanisms of early development". Curr. Top. Dev. Biol. Current Topics in Developmental Biology. 38: 1–34. doi:10.1016/S0070-2153(08)60243-4. ISBN 9780121531386. PMID 9399075.
3. Fitch KR, Wakimoto BT (1998). "The paternal effect gene ms(3)sneaky is required for sperm activation and the initiation of embryogenesis in Drosophila melanogaster". Dev. Biol. 197 (2): 270–82. doi:10.1006/dbio.1997.8852. PMID 9630751.