Overview of LR Asymmetry and PCP (Introduction)
- Left-right (LR) asymmetry refers to the consistent differences between the left and right sides of an organism (for example, the heart is normally on the left, the liver on the right).
- Planar cell polarity (PCP) is the coordinated orientation of cells within the plane of a tissue—much like how tiles are laid out evenly on a floor.
- This paper proposes that LR asymmetry may be established by mechanisms similar to PCP, meaning that the same processes which align cells in a flat sheet might also set up the body’s left–right differences.
Key Observations and Background
- Consistent LR patterning is critical for correct organ placement; errors can lead to serious birth defects.
- Traditional models have emphasized the role of motile cilia (tiny, hair-like structures) generating leftward fluid flow to break symmetry.
- However, many organisms develop LR asymmetry without relying on cilia, suggesting alternative intracellular mechanisms.
Planar Cell Polarity (PCP) and Its Role
- PCP organizes cells so that they are uniformly oriented across the tissue, similar to arranging arrows all pointing in one direction.
- It involves key proteins (such as Frizzled and Dishevelled) that become unevenly distributed within the cell.
- The paper suggests that these PCP mechanisms can amplify a small initial asymmetry and spread LR information throughout a developing embryo.
How LR Asymmetry May Be Established (Step-by-Step)
- Step 1: Breaking Symmetry
- An intracellular “starter” cue—possibly a chiral (handed) component of the cytoskeleton—provides the first directional hint.
- This is like adding the first ingredient in a recipe that sets the overall flavor.
- Step 2: Amplification via PCP
- Cells use PCP mechanisms to align their internal components and communicate their directional information to neighboring cells.
- This is similar to how a drop of dye spreads evenly through a glass of water.
- Step 3: Transmission of LR Signals
- Physiological signals—such as ion fluxes (movements of charged particles)—help establish clear differences between the left and right sides.
- Imagine electrical currents running along a circuit board, guiding the flow of information.
- Step 4: Organogenesis (Organ Formation)
- Asymmetric gene expression then directs the formation of organs on the left or right side.
- This is akin to following a detailed recipe where slight variations yield two distinct but complementary dishes.
Intracellular Mechanisms and the Role of the Cytoskeleton
- The cytoskeleton is a network of fibers that gives cells their shape and aids in moving materials inside the cell.
- Key components include microtubules and actin filaments, which can have an inherent “handedness” or chirality.
- A microtubule-organizing center (MTOC) or a basal body (the structure at the base of cilia) may function as an internal compass to orient the LR axis.
- This process is similar to using a built-in compass to line up all parts of a machine.
Evidence Supporting the Model
- Studies in frog (Xenopus) embryos show early asymmetries in protein localization, suggesting intracellular cues are at work.
- Research in fruit flies (Drosophila) reveals that key PCP components are essential for aligning cell orientation.
- Experiments with human neutrophil-like cells (HL60) indicate that even individual cells exhibit a leftward bias in movement.
- Together, these findings support the idea that cells can establish a left–right axis internally, even before external structures such as cilia come into play.
Ciliary Versus Intracellular Models
- Traditional ciliary models propose that the beating of cilia creates a leftward fluid flow to break symmetry.
- The intracellular model argues that internal cell structures, especially the cytoskeleton, set up LR asymmetry at a very early stage.
- This model can explain LR asymmetry in species that lack motile cilia and accounts for mirror-image phenomena seen in some twins.
- Think of it as choosing between using an external GPS (cilia-generated flow) and an internal compass (cellular chirality) to navigate.
Predictions and Implications of the Model
- If LR asymmetry is established intracellularly, early cell divisions (as seen in monozygotic twins) might show mirror-image patterns (often called book-ending).
- PCP components might also play a direct role in LR patterning, so mutations affecting these proteins could lead to both PCP and LR defects.
- The model predicts that manipulating intracellular transport systems should affect both the alignment of cells (PCP) and the establishment of left-right differences.
- This unified approach may help explain how large fields of cells maintain a coordinated orientation.
Limitations and Future Experimental Tests
- Many molecular details remain unclear and require further investigation.
- It is not yet definitively proven that core PCP proteins directly influence LR asymmetry in all organisms.
- Future experiments need to identify the exact intracellular factors that serve as the initial cue for LR orientation.
- Researchers can test these predictions by altering genes related to cytoskeletal organization and observing the effects on both PCP and LR patterning.
Conclusion
- The paper proposes a novel model in which left-right asymmetry is established by mechanisms similar to planar cell polarity.
- This intracellular approach may operate very early in development and is supported by evidence from multiple species.
- Understanding these processes can provide insights into developmental disorders and congenital defects.
- The study bridges traditional ciliary models and intracellular signaling, offering a comprehensive view of how body asymmetry is generated.