Meiotic Drive and Speciation.

Meiotic drive is the biased transmission of alleles from heterozygotes, contrary to Mendel's laws, and reflects intragenomic conflict rather than organism-level Darwinian selection. Theory has been developed as to how centromeric properties can promote female meiotic drive and how conflict between the X and Y chromosomes in males can promote male meiotic drive. There are empirical data that fit both the centromere drive and sex chromosome drive models.

A Genetic Bridge Between Medicine and Neurodiversity for Autism.

Autism represents a large spectrum of diverse individuals with varying underlying genetic architectures and needs. For some individuals, a single de novo or ultrarare genetic variant has a large effect on the intensity of specific dimensions of the phenotype, while, for others, a combination of thousands of variants commonly found in the general population are involved. The variants with large impact are found in up to 30% of autistic individuals presenting with intellectual disability, significant speech delay, motor delay, and/or seizures.

Genetic Approaches for Identifying and Characterizing Effectors in Bacterial Pathogens.

Microbial pathogens have coevolved with their hosts, often for millions of years, and in the process have developed a variety of virulence mechanisms to ensure their survival, typically at the host's expense. At the center of this host-pathogen warfare are proteins called effectors that are delivered by bacteria into their host where they alter the intracellular environment to promote bacterial proliferation. Many effectors are believed to have been acquired by the bacteria from their host during evolution, explaining why researchers are keen to understand their function, as this information may provide insight into both microbial virulence strategies and biological processes that happen within our own cells.

Developmental and Genetic Aspects of Desert Crops.

Deserts are hostile environments to plant life due to exposure to abiotic stresses, including high temperature, heat, high light, low water availability, and poor soil quality. Desert plants have evolved to cope with these stresses, and for thousands of years humans have used these plants as sources of food, fiber, and medicine. Due to desertification, the amount of arable land is reduced every year; hence, the usage of these species as substitutes for some crops might become one of the solutions for food production and land remediation.

From Mammals to Insects: Exploring the Genetic and Neural Basis of Eating Behavior.

Obesity and anorexia are life-threatening diseases that are still poorly understood at the genetic and neuronal levels. Patients suffering from these conditions experience disrupted regulation of food consumption, leading to extreme weight gain or loss and, in severe situations, death from metabolic dysfunction. Despite the development of various behavioral and pharmacological interventions, current treatments often yield limited and short-lived success.

The Prokaryotic Roots of Eukaryotic Immune Systems.

Over the past two decades, studies have revealed profound evolutionary connections between prokaryotic and eukaryotic immune systems, challenging the notion of their unrelatedness. Immune systems across the tree of life share an operational framework, shaping their biochemical logic and evolutionary trajectories. The diversification of immune genes in the prokaryotic superkingdoms, followed by lateral transfer to eukaryotes, was central to the emergence of innate immunity in the latter.

The Nature and Nurture of Extracellular Vesicle-Mediated Signaling.

In the last decade, it has become clear that extracellular vesicles (EVs) are a ubiquitous component of living systems. These small membrane-enclosed particles can confer diverse functions to the cells that release, capture, or coexist with them in an environment. We use examples across living systems to produce a conceptual framework that classifies three modes by which EVs exert functions: () EV release that serves a function for producing cells, () EV modification of the extracellular environment, and () EV interactions with, and alteration of, receiving cells.

Placental Evolution: Innovating How to Feed Babies.

The evolution of the placenta was transformative. It changed how offspring are fed during gestation from depositing all the resources into an egg to continually supplying resources throughout gestation. Placental evolution is infinitely complex, with many moving parts, but at the core it is driven by a conflict over resources between the mother and the baby, which sets up a Red Queen race, fueling rapid diversification of morphological, cellular, and genetic forms.

Cellular, Molecular, and Genetic Mechanisms of Avian Beak Development and Evolution.

Diverse research programs employing complementary strategies have been uncovering cellular, molecular, and genetic mechanisms essential to avian beak development and evolution. In reviewing these discoveries, I offer an interdisciplinary perspective on bird beaks that spans their derivation from jaws of dinosaurian reptiles, their anatomical and ecological diversification across major taxonomic groups, their common embryonic origins, their intrinsic patterning processes, and their structural integration. I describe how descriptive and experimental approaches, including gene expression and cell lineage analyses, tissue recombinations, surgical transplants, gain- and loss-of-function methods, geometric morphometrics, comparative genomics, and genome-wide association studies, have identified key constituent parts and putative genes regulating beak morphogenesis and evolution.

Integrating the Study of Polyploidy Across Organisms, Tissues, and Disease.

Polyploidy is a cellular state containing more than two complete chromosome sets. It has largely been studied as a discrete phenomenon in either organismal, tissue, or disease contexts. Increasingly, however, investigation of polyploidy across disciplines is coalescing around common principles.

Population Genomic Scans for Natural Selection and Demography.

Uncovering the fundamental processes that shape genomic variation in natural populations is a primary objective of population genetics. These processes include demographic effects such as past changes in effective population size or gene flow between structured populations. Furthermore, genomic variation is affected by selection on nonneutral genetic variants, for example, through the adaptation of beneficial alleles or balancing selection that maintains genetic variation.

The Molecular Substrates of Insect Eusociality.

The evolution of eusociality in Hymenoptera-encompassing bees, ants, and wasps-is characterized by multiple gains and losses of social living, making this group a prime model to understand the mechanisms that underlie social behavior and social complexity. Our review synthesizes insights into the evolutionary history and molecular basis of eusociality. We examine new evidence for key evolutionary hypotheses and molecular pathways that regulate social behaviors, highlighting convergent evolution on a shared molecular toolkit that includes the insulin/insulin-like growth factor signaling (IIS) and target of rapamycin (TOR) pathways, juvenile hormone and ecdysteroid signaling, and epigenetic regulation.

Biological Roles of Local Protein Synthesis in Axons: A Journey of Discovery.

The remit of this review is to give an autobiographical account of our discovery of the role of local protein synthesis in axon guidance. The paper reporting our initial findings was published in 2001. Here, I describe some of the work that led to this publication, the skepticism our findings initially received, and the subsequent exciting years of follow-up work that helped gradually to convince the neuroscience community of the existence and functional importance of local protein synthesis in multiple aspects of axon biology-guidance, branching, synaptogenesis, and maintenance.

Neural Stem Cell Regulation in Zebrafish.

Neural stem cells (NSCs) are progenitor cell populations generating glial cells and neurons and endowed with long-lasting self-renewal and differentiation potential. While some neural progenitors (NPs) in the embryonic nervous system are also long-lived and match this definition, the term NSC classically refers to such progenitor types in the adult. With the discovery of extensive NSC populations in the adult brain of (zebrafish) and of their high neurogenic activity, including for neuronal regeneration, this model organism has become a powerful tool to characterize and mechanistically dissect NSC properties.

De Novo Genes.

Although the majority of annotated new genes in a given genome appear to have arisen from duplication-related mechanisms, recent studies have shown that genes can also originate de novo from ancestrally nongenic sequences. Investigating de novo-originated genes offers rich opportunities to understand the origin and functions of new genes, their regulatory mechanisms, and the associated evolutionary processes. Such studies have uncovered unexpected and intriguing facets of gene origination, offering novel perspectives on the complexity of the genome and gene evolution.

Phenotypic Heterogeneity in Pathogens.

Pathogen diversity within an infected organism has traditionally been explored through the lens of genetic heterogeneity. Hallmark studies have characterized how genetic diversity within pathogen subpopulations contributes to treatment escape and infectious disease progression. However, recent studies have begun to reveal the mechanisms by which phenotypic heterogeneity is established within genetically identical populations of invading pathogens.

Regulatory Networks Underlying Plant Responses and Adaptation to Cold Stress.

Cold is an important environmental factor limiting plant growth and development. Recent studies have revealed the complex regulatory networks associated with plant responses to cold and identified their interconnections with signaling pathways related to light, the circadian clock, plant hormones, and pathogen defense. In this article, we review recent advances in understanding the molecular basis of cold perception and signal transduction pathways.

Recombination Rate Variation in Social Insects: An Adaptive Perspective.

Social insects have the highest rates of meiotic recombination among Metazoa, but there is considerable variation within the Hymenoptera. We synthesize the literature to investigate several hypotheses for these elevated recombination rates. We reexamine the long-standing Red Queen hypothesis, considering how social aspects of immunity could lead to increases in recombination.

Apoptotic and Nonapoptotic Cell Death in Development.

Programmed cell death (PCD) is an essential component of animal development, and aberrant cell death underlies many disorders. Understanding mechanisms that govern PCD during development can provide insight into cell death programs that are disrupted in disease. Key steps mediating apoptosis, a highly conserved cell death program employing caspase proteases, were first uncovered in the nematode , a powerful model system for PCD research.

Müller Glial Cell-Dependent Regeneration of the Retina in Zebrafish and Mice.

Sight is one of our most precious senses. People fear losing their sight more than any other disability. Thus, restoring sight to the blind is an important goal of vision scientists.

Regulatory Mechanisms of Aging Through the Nutritional and Metabolic Control of Amino Acid Signaling in Model Organisms.

Life activities are supported by the intricate metabolic network that is fueled by nutrients. Nutritional and genetic studies in model organisms have determined that dietary restriction and certain mutations in the insulin signaling pathway lead to lifespan extension. Subsequently, the detailed mechanisms of aging as well as various nutrient signaling pathways and their relationships have been investigated in a wide range of organisms, from yeast to mammals.

Genetics, Genomics, and Evolution.

The ciliate genus served as one of the first model systems in microbial eukaryotic genetics, contributing much to the early understanding of phenomena as diverse as genome rearrangement, cryptic speciation, cytoplasmic inheritance, and endosymbiosis, as well as more recently to the evolution of mating types, introns, and roles of small RNAs in DNA processing. Substantial progress has recently been made in the area of comparative and population genomics. species combine some of the lowest known mutation rates with some of the largest known effective populations, along with likely very high recombination rates, thereby harboring a population-genetic environment that promotes an exceptionally efficient capacity for selection.

The Clockwork Embryo: Mechanisms Regulating Developmental Rate.

Organismal development requires the reproducible unfolding of an ordered sequence of discrete steps (cell fate determination, migration, tissue folding, etc.) in both time and space. Here, we review the mechanisms that grant temporal specificity to developmental steps, including molecular clocks and timers.

Meiosis: Dances Between Homologs.

The raison d'être of meiosis is shuffling of genetic information via Mendelian segregation and, within individual chromosomes, by DNA crossing-over. These outcomes are enabled by a complex cellular program in which interactions between homologous chromosomes play a central role. We first provide a background regarding the basic principles of this program.