Home  About us  Contact
 

Parental Effects (parental + effects)

Distribution by Scientific Domains
Life Sciences100%

Selected Abstracts

PARENTAL EFFECTS AND GENDER SPECIALIZATION IN A TROPICAL HETEROSTYLOUS SHRUB

EVOLUTION, Issue 3 2000
Germá;n Avila-Sakar
Abstract., Male sterility in hermaphroditic species may represent the first step in the evolution toward dioecy. However, gender specialization will not proceed unless the male-sterile individuals compensate for fitness lost through the male function with an increase in fitness through the female function. In the distylous shrub Erythroxylum havanense, thrum plants are partially male-sterile. Using data collected throughout eight years, we investigated whether thrum individuals have an increased performance as female parents, thereby compensating for their loss of male fitness. We found that thrum plants outperformed pins in the probabilities of seed maturation and germination and long-term growth of the seedlings. In turn, pollen from pin plants achieved greater pollen tube growth rates. Our results suggest that the superior performance of the progeny of thrum maternal plants is a consequence of better seed provisioning via effects of the maternal environment, cytotype or nuclear genes. Overall, our results suggest that E. havanense is evolving toward a dioecious state through a gynodioecious intermediate stage. This evolutionary pathway is characterized by an unusual pattern of gender dimorphism with thrums becoming females and pins becoming males. We propose that this pattern may be better explained by the interaction between male-sterility cytoplasmic genes and the heterostyly supergene. [source]

A taxonomy of biological information

OIKOS, Issue 2 2010
Richard H. Wagner
Reproduction, and thus information transfer across generations, is the most essential process of life, yet biologists lack a consensus on terms to define biological information. Unfortunately, multiple definitions of the same terms and other disagreements have long inhibited the development of a general framework for integrating the various categories of biological information. Currently, the only consensus is over two general categories, genetic information, which is encoded in DNA, and non-genetic information, which is extracted from the environment. Non-genetic information is the key to understanding gene-environment interactions and is the raw material of fields such as developmental plasticity, behavior, communication, social learning and cultural evolution. In effect, differences in information possessed by individuals produce phenotypic variation. We thus define biological information as ,factors that can affect the phenotype in ways that may influence fitness'. This definition encompasses all information that is potentially relevant to organisms, which includes the physical environment. Biological information can be acquired passively from genes or via processes such as epigenetics, parental effects and habitat inheritance, or actively by organisms sensing facts about their environment. The confusion over definitions mainly concerns non-genetic information, which takes many more forms than genetic information. Much of the confusion derives from definitions based on how information is used rather than on the facts from which it is extracted. We recognize that a fact becomes information once it is detected. Information can thus be viewed analogously to energy in being either potential or realized. Another source of confusion is in the use of words outside their usual meanings. We therefore present intuitive definitions and classify them according to categories of facts in a hierarchical framework. Clarifying these concepts and terms may help researchers to manipulate facts, allowing a fuller study of biological information. [source]

A test of three hypotheses for ovariole number determination in the grasshopper Romalea microptera

PHYSIOLOGICAL ENTOMOLOGY, Issue 3 2010
BENJAMIN J. TAYLOR
Ovariole number in insects determines potential fecundity and can be influenced by genes, environmental conditions during development and parental effects. In the present study, three hypotheses are tested for ovariole number determination in the grasshopper Romalea microptera (Beauvois), which exhibits both intra- and interpopulation variation in ovariole number. In hypothesis 1, variation in ovariole number is a result of genetic variation. In hypothesis 2, ovariole number is influenced by nutrition during development. In hypothesis 3, ovariole number is influenced by maternal nutritional status. Females from four treatments are compared: low-food, high-food, daughters of low-food, and daughters of high-food. There is a relationship between parent and offspring ovariole number despite different environments, supporting hypothesis 1. Also, ovariole numbers are slightly, but significantly lower in individuals fed a low-food diet compared with a high-food diet, supporting hypothesis 2. Hypothesis 3 is not supported: starved and well-fed females produce eggs of similar mass, as well as offspring with similar numbers of ovarioles, suggesting that the nutritional status of mothers does not influence offspring mass or offspring ovariole number. The results imply that genetic variation and developmental conditions determine ovariole number in this species but maternal environment does not. These results conflict with previous studies of ovariole determination in grasshoppers and locusts. [source]

Influence of hatching asynchrony and within-brood parental investment on size, condition, and immunocompetence in nestling red-billed choughs

BIOLOGICAL JOURNAL OF THE LINNEAN SOCIETY, Issue 4 2008
EVA BANDA
Studies of hatching asynchrony have rarely assessed the effect of parental investment strategies on the development of intra-brood hierarchies using indicators of nestling quality. The influence of hatching asynchrony and other variables related to parental investment on immunocompetence was evaluated measuring T-cell mediated immune response in broods of red-billed choughs (Pyrrhocorax pyrrhocorax), a large long-living passerine with a pronounced sexual size dimorphism. The results showed that T-cell mediated immune response depends on parental effects as shown by the differences between broods on hatching asynchrony. Male nestlings were both heavier and larger than female nestlings, but there was no effect of hatching order on these traits, nor on sex differences in immunocompetence. Differential investment strategy in relation to laying order did not favour older offspring or either of the sexes. Successful reproduction in this species might be so unpredictable and infrequent that strategies of parental investment in the brood could have evolved to attempt to maximize the survival of all nestlings by avoiding within-brood hierachies of size, body condition, and immunocompetence. © 2008 The Linnean Society of London, Biological Journal of the Linnean Society, 2008, 94, 675,684. [source]