Sexual conflict explains the extraordinary diversity of mechanisms regulating mitochondrial inheritance

Background: Mitochondria are predominantly inherited from the maternal gamete, even in unicellular organisms. Yet an extraordinary array of mechanisms enforce uniparental inheritance, which implies shifting selection pressures and multiple origins. Results: We consider how this high turnover in mechanisms controlling uniparental inheritance arises using a novel evolutionary model in which control of mitochondrial transmission occurs either during spermatogenesis (by paternal nuclear genes) or at/after fertilization (by maternal nuclear genes). The model treats paternal leakage as an evolvable trait. Our evolutionary analysis shows that maternal control consistently favours strict uniparental inheritance with complete exclusion of sperm mitochondria, whereas some degree of paternal leakage of mitochondria is an expected outcome under paternal control. This difference arises because mito-nuclear linkage builds up with maternal control, allowing the greater variance created by asymmetric inheritance to boost the efficiency of purifying selection and bring benefits in the long term. In contrast, under paternal control, mito-nuclear linkage tends to be much weaker, giving greater advantage to the mixing of cytotypes, which improves mean fitness in the short term, even though it imposes a fitness cost to both mating types in the long term. Conclusions: Sexual conflict is an inevitable outcome when there is competition between maternal and paternal control of mitochondrial inheritance. If evolution has led to complete uniparental inheritance through maternal control, it creates selective pressure on the paternal nucleus in favour of subversion through paternal leakage, and vice versa. This selective divergence provides a reason for the repeated evolution of novel mechanisms that regulate the transmission of paternal mitochondria, both in the fertilized egg and spermatogenesis. Our analysis suggests that the widespread occurrence of paternal leakage and prevalence of heteroplasmy are natural outcomes of this sexual conflict. Electronic supplementary material: The online version of this article (doi:10.1186/s12915-017-0437-8) contains supplementary material, which is available to authorized users

A Model for the Generation and Transmission of Variations in Evolution

The inheritance of characteristics induced by the environment has often been opposed to the theory of evolution by natural selection. Yet, while evolution by natural selection requires new heritable traits to be produced and transmitted, it does not prescribe, per se, the mechanisms by which this is operated. The mechanisms of inheritance are not, however, unconstrained, since they are themselves subject to natural selection. We introduce a general, analytically solvable mathematical model to compare the adaptive value of different schemes of inheritance. Our model allows for variations to be inherited, randomly produced, or environmentally induced, and, irrespectively, to be either transmitted or not during reproduction. The adaptation of the different schemes for processing variations is quantified for a range of fluctuating environments, following an approach that links quantitative genetics with stochastic control theory

A dual function for Pex3p in peroxisome formation and inheritance

Saccharomyces cerevisiae Pex3p has been shown to act at the ER during de novo peroxisome formation. However, its steady state is at the peroxisomal membrane, where its role is debated. Here we show that Pex3p has a dual function: one in peroxisome formation and one in peroxisome segregation. We show that the peroxisome retention factor Inp1p interacts physically with Pex3p in vitro and in vivo, and split-GFP analysis shows that the site of interaction is the peroxisomal membrane. Furthermore, we have generated PEX3 alleles that support peroxisome formation but fail to support recruitment of Inp1p to peroxisomes, and as a consequence are affected in peroxisome segregation. We conclude that Pex3p functions as an anchor for Inp1p at the peroxisomal membrane, and that this function is independent of its role at the ER in peroxisome biogenesis

Encapsulation and Aggregation

A notion of object ownership is introduced as a solution to difficult problems of specifying and reasoning about complex linked structures and of modeling aggregates (composit objects). Syntax and semantics are provided for extending Eiffel with language support for object ownership annotation and checking. The ideas also apply to other OOPLs such as C++

Multimethods and separate static typechecking in a language with C++-like object model

The goal of this paper is the description and analysis of multimethod implementation in a new object-oriented, class-based programming language called OOLANG. The implementation of the multimethod typecheck and selection, deeply analyzed in the paper, is performed in two phases in order to allow static typechecking and separate compilation of modules. The first phase is performed at compile time, while the second is executed at link time and does not require the modules' source code. OOLANG has syntax similar to C++; the main differences are the absence of pointers and the realization of polymorphism through subsumption. It adopts the C++ object model and supports multiple inheritance as well as virtual base classes. For this reason, it has been necessary to define techniques for realigning argument and return value addresses when performing multimethod invocations.Comment: 15 pages, 18 figure

Sex determination in Bonellia viridis (Echiura : Bonelliidae) : population dynamics and evolution

In the echiuran worm Bonellia viridis Rolando, the vast majority of sexually undifferentiated larvae metamorphose into dwarf males that live inside the female when exposed to females, but differentiate into females when developing in the absence of females. By means of a spatially explicit, individual-based model the authors examine how this specific form of environmental sex determination (ESD) affects dynamics of Bonellia populations and investigate the selective advantage of ESD over the more widespread genotypic sex determination (GSD). Population dynamics of Bonellia appear rather simple and not too sensitive to parameter changes around their measured values, or to changes in distribution and sizes of inhabitable patches. Starting even from low sizes, populations soon attain equilibrium densities. Explored aspects of population dynamics indicate an advantage of ESD over GSD. Moreover, simulated invasibility experiments show that while the maternal inheritance scenario allows for fixation of GSD under some limited conditions, both the classical and proportional inheritance scenarios always lead to fixation of ESD in the population. This article also shows that only the ability of ESD larvae to adapt their ultimate sex both in competition for empty burrows and for mating within females gives them a competitive edge over nonadaptive response to feminising and/or masculinising signals and generally leads to fixation of ESD by small step evolution. The original hypothesis of Charnov and Bull thus needs to be refined in the sense that along with females forming an unpredictable resource for males, empty burrows are an unpredictable resource for femalespeer-reviewe

Glyphosate resistance in annual ryegrass (Lolium rigidum Gaud.) with multiple resistance mechanisms.

Glyphosate (N-(phosphonomethyl)glycine) is a post-emergent, systemic and non-selective herbicide for the control of annual and perennial weeds. This herbicide has very low toxicity to the mammals. The target enzyme for glyphosate in plants is 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS). Glyphosate inhibits the biosynthesis of the aromatic amino acids phenylalanine, tyrosine and tryptophan in the plant. The first case of glyphosate resistance was reported in Lolium rigidum in Australia after 15 years of persistence use of this herbicide and the number weeds reported resistant to glyphosate has increased around the world. So far, two mechanisms known to be involved in resistance to glyphosate are target-site mutation and reduced herbicide translocation. Recently, two populations of L. rigidum from Australia have been discovered with very high levels of resistance to glyphosate. This project aims to determine the levels of glyphosate resistance in these populations, investigate glyphosate resistance mechanisms in the populations and finally assess the mode of inheritance of resistance. In this project, four resistant (NLR70, SLR77, SLR80 and SLR88) and one susceptible (VLR1) L. rigidum populations were evaluated for their response to glyphosate. From the dose response experiments, the susceptible population of VLR1 was completely controlled with the recommended rate of glyphosate (450 g a.e ha⁻ ¹). In contrast, the resistant populations were not fully controlled by this herbicide rate. There was considerable variation between the populations in their resistance to glyphosate. In comparison to the susceptible population VLR1, SLR77 was 2.2 to 3.5 fold resistant to glyphosate, NLR70 was 3.7 to 8.4 fold resistant to glyphosate, SLR88 was 5.6 to 11.4 fold resistant to glyphosate and SLR80 was 8.2 to 76.7 fold resistant to glyphosate. The mechanism of glyphosate resistance in the populations was investigated. ¹⁴ C-glyphosate was used to determine the absorption and translocation of glyphosate among the populations. There was no significant difference on the absorption of ¹⁴ C-glyphosate 48 hours after treatment in the population. However, the accumulation of ¹⁴ C-glyphosate in the stem region was higher in the susceptible VLR1 population (25.9%) and in resistant SLR77 (25%) than the other three populations. The resistant populations NLR70, SLR88 and SLR80 had about half the amount of glyphosate accumulating in the stem region. These three resistant populations appear to be resistant to glyphosate as a result of reduced translocation of glyphosate to the shoot meristem. Part of the EPSP synthase gene of the susceptible and four resistant populations was amplified and sequenced to identify any changes in the nucleotide sequence. The predicted amino acid sequence from the susceptible population VLR1 was the same as the consensus sequence from other plant species in the conserved region sequenced. However, the resistant populations of NLR70, SLR77, SLR80 and SLR88 showed polymorphisms within the nucleotide sequence in this region. Single nucleotide substitutions of A for C at codon 106 were observed in the resistant populations SLR77 and SLR80. This nucleotide change is predicted to substitute threonine for proline at position 106. In the resistant population SLR88, a nucleotide substitution of T for C was observed at the same codon. This nucleotide substitution is predicted to change the amino acid from proline 106 to serine. Therefore, these three populations appear to be resistant to glyphosate as a result of a target-site mutation. An inheritance study was conducted by cross pollinating the susceptible VLR1 and resistant SLR88 population. From the dose response, the parent susceptible was completely killed with the recommended rate of glyphosate and higher rates of glyphosate were required to control parental resistant and both F₁ progenies (maternal susceptible and resistant). Both F₁ progenies showed an intermediate response to glyphosate compared with the parental populations. This indicated that the resistance to glyphosate in population SLR88 is inherited by nuclear gene(s) through the transfer of pollen during the cross pollination. It is suggested that SLR88 and SLR80 population contain both glyphosate resistant mechanisms due to the cross pollination between individuals with different resistant mechanisms. Having two resistant mechanisms results in populations being highly resistant to glyphosate compared to those with one resistance mechanism. The higher level of glyphosate resistance in these multiple glyphosate resistance populations will likely make them harder to manage.Thesis (M.Ag.Sc.) -- University of Adelaide, School of Agriculture, Food and Wine, 201