Regulation of the cytoskeleton is essential for cell migration in health and disease. Lymphocyte cytosolic protein 1 (lcp1, also called L-plastin) is a hematopoietic-specific actin-bundling protein that is highly conserved in zebrafish, mice and humans. In addition, L-plastin expression is documented as both a genetic marker and a cellular mechanism contributing to the invasiveness of tumors and transformed cell lines. Despite L-plastin’s role in both immunity and cancer, in zebrafish there are no direct studies of its function, and no mutant, knockout or reporter lines available. Using CRISPR-Cas9 genome editing, we generated null alleles of zebrafish lcp1 and examined the phenotypes of these fish throughout the life cycle. Our editing strategy used gRNA to target the second exon of lcp1, producing F0 mosaic fish that were outcrossed to wild types to confirm germline transmission. F1 heterozygotes were then sequenced to identify three unique null alleles, here called ‘Charlie’, ‘Foxtrot’ and ‘Lima’. In silico, each allele truncates the endogenous protein to less than 5% normal size and removes both essential actin-binding domains (ABD1 and ABD2). Although none of the null lines express detectable LCP1 protein, homozygous mutant zebrafish (-/-) can develop and reproduce normally, a finding consistent with that of the L-plastin null mouse (LPL -/-). However, such mice do have a profound immune defect when challenged by lung bacteria. Interestingly, we observed reduced long-term survival of zebrafish lcp1 -/- homozygotes (~30% below the expected numbers) in all three of our knockout lines, with greatest mortality corresponding to the period (4–6 weeks post-fertilization) when the innate immune system is functional, but the adaptive immune system is not yet mature. This suggests that null zebrafish may have reduced capacity to combat opportunistic infections, which are more easily transmissible in the aquatic environment. Overall, our novel mutant lines establish a sound genetic model and an enhanced platform for further studies of L-plastin gene function in hematopoiesis and cancer.
Actin assemblies are important in motile cells such as leukocytes, which form dynamic plasma membrane extensions or podia. L‐plastin (LCP1) is a leukocyte‐specific calcium‐dependent actin‐bundling protein that, in mammals, is known to affect immune cell migration. Previously, we generated CRISPR/Cas9 engineered zebrafish lacking L‐plastin (lcp1−/−) and reported that they had reduced survival to adulthood, suggesting that lack of this actin‐bundler might negatively affect the immune system. To test this hypothesis, we examined the distribution and migration of neutrophils and macrophages in the transparent tail of early zebrafish larvae using cell‐specific markers and an established wound‐migration assay. Knockout larvae were similar to their heterozygous siblings in having equal body sizes and comparable numbers of neutrophils in caudal hematopoietic tissue at 2 days postfertilization, indicating no gross defect in neutrophil production or developmental migration. When stimulated by a tail wound, all genotypes of neutrophils were equally migratory in a two‐hour window. However, for macrophages we observed both migration defects and morphological differences. L‐plastin knockout macrophages (lcp1 −/−) still homed to wounds but were slower, less directional and had a star‐like morphology with many leading and trailing projections. In contrast, heterozygous macrophages lcp1 (+/−) were faster, more directional, and had a streamlined, slug‐like morphology. Overall, these findings show that in larval zebrafish L‐plastin knockout primarily affects the macrophage response with possible consequences for organismal immunity. Consistent with our observations, we propose a model in which cytoplasmic L‐plastin negatively regulates macrophage integrin adhesion by holding these transmembrane heterodimers in a “clasped,” inactive form and is a necessary part of establishing macrophage polarity during chemokine‐induced motility.
Actin dynamics are important in motile cells such as leukocytes which form actin-rich extensions of the plasma membrane. L-plastin (LCP1) is a leukocyte-specific calcium-dependent actin-bundling protein that in mammals is known to affect immune cell migration and synapse formation. Previously, we generated CRISPR/Cas9 engineered zebrafish lacking L-plastin (lcp1-/-) and reported that they had somewhat reduced survival to adulthood, suggesting that lack of L-plastin might negatively affect the immune system. To test this hypothesis, we examined the distribution and migration of neutrophils and macrophages in the transparent tail of early zebrafish larva, using cell-specific markers and an established wound-migration assay. By crossing genotyped parents of our established L-plastin mutant lines, we were able to generate either 1:1 clutches of lcp1 heterozygous: homozygous siblings or 1:2:1 clutches representing all possible sibling combinations of wild type and mutant alleles. Knockout larvae were similar to their heterozygous siblings in having equal body sizes and comparable numbers of neutrophils in caudal hematopoietic tissue at 2 days post-fertilization (dpf), indicating no gross defect in neutrophil production or developmental migration. When stimulated by a tail wound all genotypes of neutrophils were equally migratory in a 2-hour window. However for macrophages we observed both migration defects and morphological differences. L-plastin knockout macrophages still homed to wounds but were slower, less directional and had a star-like morphology with many leading and trailing projections. In contrast, wild type macrophages were faster, more directional, and had a more streamlined, slug-like morphology. Overall, these findings show that in larval zebrafish L-plastin knockout primarily affects the macrophage response with possible consequences for organismal immunity. Consistent with these, we propose a model in which cytoplasmic L-plastin negatively regulates macrophage integrin adhesion by holding these transmembrane heterodimers in a 'clasped', inactive form.
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