Like many neuronal receptors, Dscam proteins have multiple functions, with repulsive and attractive roles that are dependent on the type of
ligand that they interact with.
Immunity Invertebrates do not have antibody-based immune systems. Instead, invertebrates rely on their innate immune system to eliminate infectious entities. The task of detecting and responding to a diverse pool of infectious agents are accomplished by
germline encoded
pattern recognition receptors (PRRs), which detect different patterns associated with the molecular markers to initiate an immune response. The role of Dscam in the fly immune response was demonstrated by an
RNAi mediated depletion experiment of DSCAM in which it was found to be associated with the cells that play a role in the fly's immune system. Dscam is found to have a role in
phagocytosis in insects. The splicing pattern of the gene accompanying the phagocytic activity is specific to the type of infectious pathogen. In mosquitoes, the silencing of the
Anopheles gambiae Dscam (AgDscam) disables its capacity to fight
Plasmodium. The specificity of the Dscam recognition mechanism allows the mosquitoes of this species to differentiate the infection between bacteria and
Plasmodium, and between
Plasmodium berghei and
Plasmodium falciparum.
Regulation of synaptogenesis Self-avoidance is a mechanism where the
neuronal processes from the cell repel each other during arborization and axon branching to avoid
fasciculation and clumping. Self-avoidance is necessary to prevent extensive overlapping in the arborization pattern and to facilitate the coverage of the neuronal processes across different regions of the nervous system during development. DSCAM is recognized to be involved in this process in both vertebrates and invertebrates during neural development. Cell aggregation assays show that cell adhesion molecules, such as DSCAM, belonging to the
immunoglobulin superfamily bind homophilically and specifically. These molecules also appear to have a role in
chemoattraction and repulsion. Dscam1 of
Drosophila may be one of the molecules involved in counteracting the
netrin-dependent chemoattraction between neuronal processes during the neural development stage. The isoform-specific binding properties of Dscam, during homophilic repulsion, are the basis of self-avoidance, which is a crucial developmental mechanism for uniform distribution of axonal and dendritic processes in the formation of synaptic fields. Furthermore, DSCAM is thought to have a role in 'tiling' during
Drosophila's neuronal development. Tiling is a mechanism in which the processes from cells that share the same function work to create nerve bundles in a defined territory to create a pattern of non-overlapping dendritic or axonal fields. Dscam1 and Dscam2 appear to be involved in axonal branching and tiling in
Drosophila. Tiling occurs when homophilic repulsion mediated by Dscam2 prevents the processes of the same class of cells from overlapping. While both Dscam1 and Dscam2 mediate homophilic repulsion, the Dscam2 gene (unlike Dscam1) only encodes two alternative isoforms and thus lacks possible molecular diversity. Consequently, the role of Dscam2, in either self-avoidance or cell-type-specific avoidance, occurs depending on which isoform or ratio of isoforms that the neuron expresses. ==Interactions==