Centric diatoms: While centric diatoms have little or no direct substratum motility as seen with many of the pennate diatoms, they can modify their position in the water column [1.36] and there has been some great recent work demonstrating there is direct regulation of diatom buoyancy [1.16] [1.34]. We encourage readers to explore this topic as well if they wish to be further engaged in current approaches regarding functional regulation of centric movement.
Composition of diatom mucilage: Understanding the chemical and physical nature of diatom mucilages and secretions is important to understanding the way that diatoms can use mucilage for a variety of functions. It is likely that different materials are secreted for purposes such as protection of cells during reproduction, and holding the two halves of their frustule together, stalk production, as well as making connections that can move their position relative to the frustule. A number of prior investigations have begun to look into this (e.g., [1.26] [1.27]) and it seems like a great opportunity for continued future work. It has practical impact in the study of biofouling [1.50] and underwater adhesives.
Photoreception: A number of labs have begun to investigate the types of molecules responsible for photoreception in algae. While numerous types of promising candidates have been described (e.g. [1.12] [1.29] [1.31] [1.35] [1.37]), there have been no definitive studies pointing to specific molecules driving the diurnal, light aggregation, or light avoidance behaviors. Better knowledge of the specific light and chemical receptors in diatoms, and how they alter the processes of force generation and directional bias in cells will be needed too. Light piping in the colonial pennate diatom Bacillaria has been postulated [1.21], but not yet tested.
Effect of morphogenetic alterations on motility: Numerous diatom species have alternative morphologies based on the environmental conditions (e.g., [1.9] [1.30]). In addition, while numerous pennate diatoms are basically symmetric about the transapical plane dividing the two raphe branches (e.g., Navicula spp.), there are also numerous other species (e.g., Gomphonema spp.) in which the raphe runs down the apical axis, but the morphology at the two ends is decidedly different. There are also species where the raphe is displaced along valvar wings and the break between branches is at one end (e.g., Surirella spp.). The characterization of such species, correlating the valve morphology and raphe morphology with motility characteristics, seems like a productive line of research to better determine the relationship between wall structure and movement, and whether the motility associated with the ends of raphe branches can be regulated independently.
Cytoskeletal organization: The actin cables comprised of large bundles of actin filaments underlying the raphe in motile raphid diatoms appear essential to active, well-regulated motility [1.41]. But the connection between the filaments of the cables and the raphe mucilage fibers remains poorly understood. More research definitely needs to be done on more detailed organization of the actin filaments within the larger ultrastructure and orientation of the cell and frustule. The polarity of the two actin cables (parallel? antiparallel?) and relative placement to the membrane are crucial details to resolve.
Evolutionary relationships of motility: While diatom gliding is a somewhat unique form of motility, a clearer understanding of the movement would also arise from a better knowledge of its evolutionary basis. For example, some algae such as desmids or filamentous bacteria can move via direct mucilage secretion through specialized pores [1.10] [1.14] [1.15], some algae like Chara use membrane-associated actin cables to generate intracellular movement and cytoplasmic streaming [1.25] [1.46], and in some cases algae that normally swim (e.g., Chlamydomonas) can glide over a surface using the membranous intracellular transport powered by motor proteins using the underlying cytoskeleton [1.45]. Gliding in myxobacteria [1.49] is similar to that of diatoms. Studying how some of these types of components might be related to diatom gliding could yield important insights into both the evolution and physiology of these types of movements.
In addition to these, there are numerous areas that are ripe for fresh research. Diatom species are a foundational food component to many aquatic ecosystems, and are quite sensitive (in motility, metabolism and reproduction) to temperature fluctuations. Thus, detailed ecological studies of effects of diatoms in changing temperatures would be crucially important to understand the ecological impact of diatoms related to temperature change, daily and long-term. We know that mucilage strength and resilience, and subsequent motile abilities, are all related to temperature and could be severely affected by small temperature changes. Knowing how these motility and adhesion attributes change, and which species are more sensitive, would be a great boost to understanding the ecological ramifications of climate change. Another interesting topic not fully resolved and of interest is determining how expensive such motility really is for the diatoms, as they leave large amounts of extruded carbohydrate externally to the frustule and need to constantly synthesize materials associated with motility. While such mucilage also becomes connected to other ecological issues with a tight-knit algal community, the energy costs for an individual cell is an intriguing question.
Diatom secretions are also strongly related to many ecological structures of aquatic ecosystems [1.4]. They affect soil and sediment stability, food access during diurnal movements, food accessibility in stalked versus benthic forms, and connection and stability within complex algal communities where diatoms can work to interconnect various forms of algae. It would be worthwhile to investigate the details of the mucilage from various forms and species of diatoms in different communities (and, as above, their changes as a function of temperature) in an attempt to understand which secretions (e.g., motility related versus non-motility related) are most important for different aspects of an algal community. Investigating the changes in these secretions, and in the resulting motile characteristics of the cells, will provide a much stronger understanding of the ways diatoms are functionally integrated within an algal community. Moreover, understanding the energetics of motility is crucial to understanding the constraints placed on a cell in its generation of movement. While a recent work has begun to consider the energetics of diatom movement during diurnal migration [1.38], there is much work to be done in understanding the energy consumed by diatoms under different ecological situations.
There is also a strong need for additional work into high resolution forms of microscopy to determine, in living cells, where mucilage is being secreted, the characteristics of the mucilage secreted from the raphe, and the way in which raphe connections to the substratum are correlated with stimuli (e.g., light irradiation) affecting the direction and motility. Understanding the molecular controls on motility within the cell needs additional research to identify the receptors and molecules responsible for regulation and synthesis of the different enzymes and substances needed in the motile machinery.
Despite these many open areas of diatom research into motility, it is also important to reiterate what we do know about diatom motility:
Adhesion and motility are closely coupled: The requirement for raphe secreted mucilage to adhere to a solid or semi-solid substratum in order to move is well supported. Diatom secretions are crucial for a number of cell processes, including protection of protoplasts during cell conjugation, attachment and integrity of cell wall components, formation of stalks, and motility of cells. Inhibitors of diatom secretion inhibit motility, and diatom motility is strongly correlated with the degree to which it can adhere to a substratum. In some research, it has been shown that diatoms on the underside of a surface can also pull themselves back up to a motile confirmation after briefly remaining adhered by only a single end of the cell.
Motile characteristics are species specific: Numerous lines of research have shown that path curvature, mean path lengths, light wavelength stimuli, speed, and strength of adhesion during motility during movement are all species specific. In this way, species determination can be made by distinct characteristics of motile behavior, in addition to more typically used aspects such as frustule ornamentation and detail and life history. Thus, diatoms, like most other organisms, are not just a set of morpho-species separated by evolutionary diversification