In a groundbreaking discovery that challenges long-held dogmas in cellular biology, researchers have uncovered a novel mode of interaction between somatic and germ cells in the ovaries of certain myriapod species. Traditionally, the epithelial cells surrounding animal organs are known to exhibit a strict apicobasal polarity, where their apical surfaces interact directly with neighboring cells or the external environment, and their basal surfaces remain insulated by a robust, wall-like structure called the basement membrane. This membrane, composed primarily of extracellular matrix proteins, typically acts as an impermeable barricade, preventing direct cellular contact between distinct tissue compartments. However, recent studies focusing on the myriapod species Thereuonema tuberculata and Hanseniella caldaria have upended this classical view, revealing that follicle cells in these species extend their cytoplasmic processes through the basement membrane to establish direct basal contact with oocytes.
The basement membrane has conventionally been understood as a crucial structural and biochemical barrier regulating cell polarity, tissue compartmentalization, and morphogenetic signaling pathways. In vertebrates and many invertebrates, this membrane delineates the boundary between somatic and germinal cells, ensuring the integrity of each cellular environment. The discovery that follicle cells in certain myriapods bypass this barrier introduces a previously unknown flexibility in the architecture of epithelial tissue, calling into question foundational assumptions about cell-cell communication and specialization in animal organs.
Follicle cells, which surround and support developing oocytes, have been well-documented to interface with germ cells primarily through their apical domain. This intimate apposition facilitates nutrient exchange, signaling, and mechanical support crucial for oogenesis. The observation that, in Thereuonema tuberculata and Hanseniella caldaria, follicle cells invert this arrangement by targeting the basal domain toward oocytes is an evolutionary and developmental novelty. Detailed microscopy revealed that these follicle cells send protrusions through minute, localized disruptions in the basement membrane matrix, effectively punching cellular “tunnels” that establish direct cytoplasmic contact sites with oocytes.
This discovery carries profound implications for our understanding of epithelial polarity and cell communication. The classical model posits a fixed polarity axis mediated by the basement membrane, which influences cellular differentiation, directionality, and function. The evidence that epithelial cells can actively penetrate the basement membrane and establish contact with germ cells suggests that the polarity of cells and the structural functions of basement membranes are more plastic and adaptable. This may reflect an evolutionary adaptation peculiar to these myriapods, possibly linked to their reproductive strategies or developmental constraints.
From a mechanistic perspective, the ability of follicle cells to extend cytoplasmic processes through the basement membrane might involve specialized cytoskeletal rearrangements and molecular machinery to degrade or remodel extracellular matrix components. Proteolytic enzymes, matrix metalloproteinases, or specialized adhesion molecules could facilitate this unique cellular invasion. Determining the molecular players involved will be critical for understanding whether such interactions are confined to specific taxa or represent a more widespread but previously overlooked biological phenomenon.
This observation further compels a reevaluation of how cellular boundaries and compartmentalization are defined in complex tissues. Rather than serving solely as impermeable barriers, basement membranes might act as dynamic interfaces that permit selective cellular transit or communication under tightly regulated circumstances. Such functional plasticity could be essential during critical developmental stages, tissue regeneration, or in pathological contexts.
This work also opens new research avenues into how extracellular matrix dynamics and cell polarity interplay during organogenesis. It may further inform biomedical investigations into basement membrane-associated pathologies such as cancer metastasis, fibrosis, or congenital disorders, where remarkable alterations in basement membrane integrity and cell invasiveness are observed.
In sum, the revelation that ovarian follicle epithelial cells in Thereuonema tuberculata and Hanseniella caldaria can bypass the basement membrane and form direct basal contacts with oocytes presents a significant shift in our understanding of tissue organization, cell polarity, and somatic-germ cell communication. These findings underscore the complexity and plasticity of biological systems and underscore the need for broader, comparative anatomical and developmental investigations to fully appreciate the diversity of cellular strategies across species.
Subject of Research: Cellular polarity and interactions between follicle (somatic) cells and oocytes in myriapod ovaries.
Article Title: Soma–germ contact across the basement membrane in the ovary
News Publication Date: 23-Apr-2025
Web References:
10.1098/rsbl.2025.0056
Image Credits: Chikami Yasuhiko
Keywords: Organismal biology; Comparative anatomy; Reproductive system; Ovarian follicles; Tissue; Epithelium; Invertebrates; Arthropods; Morphology
Tags: basement membrane functionscellular architecture flexibilityepithelial cell polarityextracellular matrix interactionsgerm cell development mechanismsmyriapod reproductive biologymyriapod species researchnovel cellular biology discoveriesoocyte and follicle cell dynamicsovarian cell communicationsomatic and germ cell interactiontraditional cellular dogmas challenged
