Denise B. Flaherty (she/her)

Understanding the geographic distribution of genetic diversity of imperiled species across all life history stages, and identifying the factors that shape those distributions, are key to maintaining long-term genetic diversity and the health of populations. This knowledge is particularly important for highly mobile marine organisms, whose extensive movements can obscure patterns of population structure. We substantially expand the genetic dataset for the critically endangered hawksbill turtle, Eretmochelys imbricata, in the West Atlantic, focusing on the southwest Caribbean. Our dataset comprises nearly 3,000 mtDNA control region sequences (740 bp) assigned to 60 haplotypes: 41 found in rookeries and 47 in foraging grounds, including 17 orphan haplotypes. The Panama metapopulation represents a major center of genetic diversity for hawksbills, with one of the highest recorded diversity values for the species (h = 0.749, π = 0.00782), nine endemic haplotypes, and four additional haplotypes that are endemic to the Southwest Caribbean. Rarefaction analyses indicate that a sample size of at least 100 is necessary to reveal true haplotype richness at most rookeries. Many-to-many mixed stock analyses, which incorporated rookery size and distance priors for 19 rookeries and 15 developmental foraging grounds, suggest that hatchlings from rookeries in the southwest Caribbean are distributed among multiple, widely-spaced foraging grounds across the West Atlantic. These results support a groups-to-soups analogy, in which genetic variability across foraging grounds represents a continuum of genetic diversity that can best be explained by a “current conveyor” model. The dataset shows that philopatry in hawksbills is not absolute, resulting in true biological dispersal and geneflow on local, regional, and ocean-basin scales, likely facilitated by dispersion during the epipelagic stage. The important contribution of oceanographic features to genetic variation at rookeries and foraging grounds is corroborated, as is the concept of oceanographic “dispersal shadows” that limit geneflow between rookeries. This study reinforces the assertion that all range states share responsibility for the recovery of the hawksbill, because foraging grounds, that are often at distant locations, are the source of future generations of reproductive adults. We also document significant movement by hawksbills between regional management units (RMUs) 29 and 30 in the West Atlantic. The Spanish version of the Abstract is available in Supplementary File 1.

In Drosophila embryonic CNS, the multipotential stem cells called neuroblasts (NBs) divide by self-renewing asymmetric division and generate bipotential precursors called ganglion mother cells (GMCs). GMCs divide only once to generate two distinct post-mitotic neurons. The genes and the pathways that confer a single division potential to precursor cells or how neurons become post-mitotic are unknown. It has been suggested that the homeodomain protein Prospero (Pros) when localized to the nucleus, limits the stem-cell potential of precursors. Here we show that nuclear Prospero is phosphorylated, where it binds to chromatin. In NB lineages such as MP2, or GMC lineages such as GMC4-2a, Pros allows the one-division potential, as well as the post-mitotic status of progeny neurons. These events are mediated by augmenting the expression of Cyclin E in the precursor and repressing the expression in post-mitotic neurons. Thus, in the absence of Pros, Cyclin E is downregulated in the MP2 cell. Consequently, MP2 fails to divide, instead, it differentiates into one of the two progeny neurons. In progeny cells, Pros reverses its role and augments the downregulation of Cyclin E, allowing neurons to exit the cell cycle. Thus, in older pros mutant embryos Cyclin E is upregulated in progeny cells. These results elucidate a long-standing problem of division potential of precursors and post-mitotic status of progeny cells and how fine-tuning cyclin E expression in the opposite direction controls these fundamental cellular events. This work also sheds light on the post-translational modification of Pros that determines its cytoplasmic versus nuclear localization.

Given the prevalence of skin cancer, sunscreens are recommended by dermatologists including the American Academy of Dermatology to protect skin from harmful ultraviolet rays. Unfortunately, this leads to an estimated 14,000 tons of sunscreen entering waterways each year. Many of the chemicals in sunscreens, such as oxybenzone and benzophenone-2, are indicated to have adverse effects on corals and other aquatic life. As an eco-conscious alternative, physical barrier sunscreens, such as non-nano-titanium dioxide (TiO ), have been suggested as a replacement. This study examines the impact of a non-nano-TiO -based sunscreen over a nationally sold brand of sunscreen containing oxybenzone, on clownfish (Amphiprion ocellaris). Animals were evaluated for mortality, swimming behavior, and feeding behavior. Our data indicate that at an exposure level of 100 mg/L oxybenzone-containing sunscreen had a negative impact on mortality, leading to 25% death by the end of the 97-h testing period. Negative impacts on behavior were even more dramatic for the 100 mg/L oxybenzone-containing sunscreen, with 100% of the animals failing to feed over the first 49 h of testing and 100% of animals demonstrating abnormal swimming behavior over the entire testing period. By comparison, the non-nano-(TiO ) sunscreen at 100 mg/L had little (6.7%) negative impact on mortality and feeding. While swimming behavior was disrupted during the first 25 h of testing (26.7% abnormal movement), animals recovered well over the remainder of the testing period (out to 97 h).

TTN-1, a titin like protein in Caenorhabditis elegans, is encoded by a single gene and consists of multiple Ig and fibronectin 3 domains, a protein kinase domain and several regions containing tandem short repeat sequences. We have characterized TTN-1's sarcomere distribution, protein interaction with key myofibrillar proteins as well as the conformation malleability of representative motifs of five classes of short repeats. We report that two antibodies developed to portions of TTN-1 detect an ∼ 2-MDa polypeptide on Western blots. In addition, by immunofluorescence staining, both of these antibodies localize to the I-band and may extend into the outer edge of the A-band in the obliquely striated muscle of the nematode. Six different 300-residue segments of TTN-1 were shown to variously interact with actin and/or myosin in vitro. Conformations of synthetic peptides of representative copies of each of the five classes of repeats—39-mer PEVT, 51-mer CEEEI, 42-mer AAPLE, 32-mer BLUE and 30-mer DispRep—were investigated by circular dichroism at different temperatures, ionic strengths and solvent polarities. The PEVT, CEEEI, DispRep and AAPLE peptides display a combination of a polyproline II helix and an unordered structure in aqueous solution and convert in trifluoroethanol to α-helix (PEVT, CEEEI, DispRep) and β-turn (AAPLE) structures, respectively. The octads in BLUE motifs form unstable α-helix-like structures coils in aqueous solution and negligible heptad-based, α-helical coiled-coils. The α-helical structure, as modeled by threading and molecular dynamics simulations, tends to form helical bundles and crosses based on its 8-4-2-2 hydrophobic helical patterns and charge arrays on its surface. Our finding indicates that APPLE, PEVT, CEEEI and DispRep regions are all intrinsically disordered and highly reminiscent of the conformational malleability and elasticity of vertebrate titin PEVK segments. The proposed presence of long, modular and unstable α-helical oligomerization domains in the BLUE region of TTN-1 could bundle TTN-1 and stabilize oblique striation of the sarcomere.

Lamins form structural filaments in the nucleus. Mutations in A-type lamins cause muscular dystrophy, cardiomyopathy and other diseases, including progeroid syndromes. To identify new binding partners for lamin A, we carried out a two-hybrid screen with a human skeletal-muscle cDNA library, using the Ig-fold domain of lamin A as bait. The C-terminal region of titin was recovered twice. Previous investigators showed that nuclear isoforms of titin are essential for chromosome condensation during mitosis. Our titin fragment, which includes two regions unique to titin (M-is6 and M-is7), bound directly to both A- and B-type lamins in vitro. Titin binding to disease-causing lamin A mutants R527P and R482Q was reduced 50%. Studies in living cells suggested lamin-titin interactions were physiologically relevant. In Caenorhabditis elegans embryos, two independent C. elegans (Ce)-titin antibodies colocalized with Ce-lamin at the nuclear envelope. In lamin-downregulated [lmn-1(RNAi)] embryos, Ce-titin was undetectable at the nuclear envelope suggesting its localization or stability requires Ce-lamin. In human cells (HeLa), antibodies against the titin-specific domain M-is6 gave both diffuse and punctate intranuclear staining by indirect immunofluorescence, and recognized at least three bands larger than 1 MDa in immunoblots of isolated HeLa nuclei. In HeLa cells that transiently overexpressed a lamin-binding fragment of titin, nuclei became grossly misshapen and herniated at sites lacking lamin B. We conclude that the C-terminus of nuclear titin binds lamins in vivo and might contribute to nuclear organization during interphase.

In Caenorhabditis elegans, the gene unc- 89 is required for A-band organization of striated muscle. In mammals, a likely homolog of UNC-89, called obscurin, has been described and found to be localized at both the M-lines and Z-discs of striated muscle. Here, we show that the coding sequence for unc- 89 is larger than originally thought, and that the gene encodes at least four major isoforms: UNC-89-A (original isoform, 732 kDa), UNC-89-B (potentially 900 kDa), and UNC-89-C and UNC-89-D (each 156 kDa). UNC-89-C and -D, except for unique N-terminal tails of eight and 11 residues, respectively, are co-linear with the C terminus of UNC-89-B. The unc- 89 complex transcription unit contains at least three promoters: one directing UNC-89-A and -B primarily in body-wall and pharyngeal muscle, one internal promoter directing expression of UNC-89-C primarily in body-wall muscle, and one internal promoter directing expression of UNC-89-D primarily in a few muscle cells of the tail. Isoform-specific RNA interference resulted in a muscle structural phenotype similar to a typical unc- 89 mutant, but with varying degrees of severity. Antibodies generated to the interkinase region shared by the UNC-89-B, -C and -D isoforms localize to the middle of A-bands, like previously-described UNC-89 antibodies, and detect proteins on immunoblots consistent with the proposed gene organization and additional isoforms. The three new UNC-89 isoforms contain two protein kinase domains, of the myosin light chain kinase (MLCK) family. UNC-89-B contains two complete protein kinase domains, designated PK1 and PK2. UNC-89-C and -D begin with partial kinase domains, PK1-C and PK1-D. Homology modeling suggests that PK2 is catalytically active, PK1 is inactive, and that PK1-C and PK1-D have similar structures at their N termini that may create sites for interaction with other proteins.

To further understand the assembly and maintenance of the muscle contractile apparatus, we have identified a new protein, UNC-98, in the muscle of Caenorhabditis elegans. unc-98 mutants display reduced motility and a characteristic defect in muscle structure. We show that the major defect in the mutant muscle is in the M-lines and dense bodies (Z-line analogs). Both functionally and compositionally, nematode M-lines and dense bodies are analogous to focal adhesions of nonmuscle cells. UNC-98 is a novel 310-residue polypeptide consisting of four C2H2 Zn fingers and several possible nuclear localization signal and nuclear export signal sequences. By use of UNC-98 antibodies and green fluorescent protein fusions (to full-length UNC-98 and UNC-98 fragments), we have shown that UNC-98 resides at M-lines, muscle cell nuclei, and possibly at dense bodies. Furthermore, we demonstrated that 1) the N-terminal 106 amino acids are both necessary and sufficient for nuclear localization, and 2) the C-terminal (fourth) Zn finger is required for localization to M-lines and dense bodies. UNC-98 interacts with UNC-97, a C. elegans homolog of PINCH. We propose that UNC-98 is both a structural component of muscle focal adhesions and a nuclear protein that influences gene expression.